Artificial pollinators are cool, but not the solution

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beekeeping

Ecology is not a dirty word

Agreed, bees and other insect pollinators are under threat globally from multiple human pressures. If pollinators disappear completely from an ecosystem, their loss will affect the structure of those ecosystems and the natural foods and fibres we use from the ecosystem. So, finding solutions to the problem of pollinator decline are imperative.

This is why the robo bees story sounds like such a seductive idea. Imagine creating tiny drones with hairs on them that can be programmed to do a bee’s job? Wow! We are off the hook.

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HiveTool.net – Online Hive Monitoring

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beekeeping

I thought I’d share a resource which I have used the past three years. Hivetool.net monitors hives located throughout the world. The software is open source and they have all the information regarding how to install the monitoring equipment on their webpages. Additionally they try to make the equipment easy on the pocketbook so more people can participate. In my area of South Carolina one of my club members volunteered to install the software and sensors on her hive a few years ago. I can even claim a small part of the effort by building the waterproof housing and stand. The benefits I have gained have been well worth the effort. From local seasoned beekeepers  I have learned the approximate dates for local nectar flows and dearth periods. But with the monitoring of her hive I can now see the actually change of entering the nectar flow by watching the trending weight gain of the hive. More information such as temperature changes indicating swarm preparation, humidity, rainfall, bee counts, can all be monitored depending on the sensors attached. All from the comfort of your PC. Have a look at some of the active hives on the website. Here’s ours in the Midlands of South Carolina. SC008

Source: HiveTool.net

Hivetool™  is an open source project comprised of beekeepers who work with technology as technicians, engineers, programmers and database and system administrators. Our goal is to produce software and hardware tools to monitor, manage and research bees and honey production. See hivetool.org for software, hardware recommendations, instructions, plans and user manuals. Hivetool.net provides real time access to the network of hives. Hive data for research is warehoused at The Data Center for Honeybee Research.

The software is Linux based, although it should run on Windows. Readily available, commercial, off the shelf, consumer grade (low cost) hardware is used. The software supports as many different brands of hardware as possible, to avoid being locked into one vendor, technology or computing platform as technology advances so rapidly.
A database is being populated with every variable we can measure, both in the hive (e.g. weight, temperature, humidity, bee counts, audio, video), ambient conditions (solar radiation, barometric pressure, rain, wind, dew point), and hive parameters (location, elevation, orientation, hive design, foundation material, etc.) The data is both for our own research and management and for any other beekeeper, researcher or student for data mining.

There are currently over 20 hives on-line in California, Georgia, Iowa, North Carolina, and South Carolina. By the end of the summer, more hives in Colorado, Florida, Michigan, and Oregon should be on-line. Other facets of the project in the works are a smart phone app that will interface to the scale, temperature probes, etc for remote yards and a video camera bee counter.

All the data is available for download by anyone at anytime. We welcome engineers, programmers, scientists, researchers, bee keepers, and citizen scientists from anywhere around the world and invite you to join our effort.

Open Source/Open Notebook

Hivetool™ is an open source project. Wikipedia defines open source as a) universal access via free license to a product’s design or blueprint, and b) universal redistribution of that design or blueprint, including subsequent improvements to it by anyone.

Originally, open source just applied to software, then hardware. Hivetool™ also open sources the data and research results (open notebook).

Again from Wikipedia: Open notebook is the practice of making the entire primary record of a research project publicly available online as it is recorded. There is no ‘insider information’. It is the logical extreme of transparent approaches to research and explicitly includes the making available of failed, less significant, and otherwise unpublished experiments.

We want peer review to start at the beginning of the experimental process to make the research as quick and efficient as possible. Why wait until the experiment ends with poor results to point out the flaws in the experimental techniques?

Goals

1. Hive Management: Help the beekeeper determine when to feed, split, super and provide data to validate or invalidate beekeeping lore, practices, equipment, techniques, treatments.

2. Climate and Land Use Research: Provide data to NASA for analysis. Eventually do our own research as the hive database is built up over time.

3. Education and Bee Science: Attract students to education and science.

Source: HiveTool.net

ProVap110 Oxalic Acid Sublimator by sassafrasbeefarm

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beekeeping, chores, management, oxalic acid, pests, product review, Provap110, varroa, varroa destructor, varroa mites

Product Review:

For Varroa mite control, I sprung for a ProVap110 this year. I put it through the paces this week and thought I’d report on it here.

View Video Here:

Disclaimer first: Yes, Larry of OxaVap is a friend of mine. We met at a South Carolina Beekeepers Association conference several years ago and hit it off talking bees non stop for the duration of the conference. This was all before oxalic acid was approved for use in the United States. Larry told me then it would be the next big deal in Varroa mite control and apparently he was right as it was approved a couple years later. (Larry also told me where U.S. beekeepers were already ordering vaporizers from across the border in Canada.) Anyway, Larry and I always look forward to conferences and hanging out, telling bee stories when we can.

Before getting the ProVap110 I was using two Varrox, pan type ,vaporizers. Using two really sped up my mite treatments. Duh, twice as fast, right? No, don’t ask me how but everything moved faster and down time between hives was less so I really think I was doing the job in less than half the time than with one.

Recently, Larry suggested I needed to try the ProVap110 but I was resistant due to the issue of needing AC current. He said that most inexpensive car/truck inverters would do the job as it only used 250 watts and 2.2 amps. I checked and Harbor Freight had an inexpensive inverter. But I really wanted to be able to treat without having to drive my truck into sometimes muddy out yards. Larry assured me that a long extension cord run would not be a problem but I resisted and bought a small WEN 1800watt generator. I do plan on buying that inverter as well but the WEN1800w is under 50 pounds and, so far, I really like it and don’t have to worry about getting my truck stuck in a muddy out yard field while vaporizing mites.

One morning this week I oxalic acid vaporized 32 hives in about an hour and 15 minutes. As with the old Varrox, you still have the setup time of placing IPM boards under screened bottom boards to help seal the hive as well as a damp dishcloth across the entrance. I left the WEN1800w generator in the back of my truck and used a 50 ft extension cord. The extension cord had no noticeable effect on the operation as the ProVap performed exactly as the enclosed paperwork stated it would. I will use a 100 ft extension next time to see if that has any effect. The ProVap110 took about 2 to 3 minutes to reach its operating temperature of 230C. The unit adjusts to maintain that temperature throughout its use. I’ll place a link to a video in this post for those who have not seen how it operates. Basically, after it reaches its operating temperature a measured amount of OA is placed in a cup and attached to the ProVap110 while inverted. The nozzle is inserted into a 1/4″ predrilled hole in the hive body and the unit is spun around to its upright position causing the OA to drop into the 230C pan. The temperature readout dropped to approximately 208C when the OA came in contact with the heating unit and immediately began its rise back to 230C. Within about 20 seconds the temperature had returned to 230C and I removed the unit from the hive. An additional “cup” is provided so the user can prepare the dose for the next hive during the 20 second wait. And so it goes hopscotching down the row of hives.

Some things I learned are: 1) Hole placement is more critical than I first expected. I had used a homemade template based on the instruction sheet and some of the holes were drilled into handholds which caused me to have to hold the unit in place instead of leaving it to prep the next dose. The instructions say drill the hole 3 to 4 inches up from the bottom . I will drill future holes below the handholds in the lower box – if you use cleats drill well below. You want the vapors to circulate readily once inside the hive so make the hole in that area where the frames are narrow (lower half) to allow for the bees to move around the frame. 2) The tube that sends the vapor into the hive is copper and about 3/4″ in length. That makes sense since it is going into a hive body with a thickness of 3/4″. Longer and it could bottom out on a frame inside. Unrelated to the tube length but I’d like the tube to be made of a harder metal than copper if possible – I am uncomfortable with the possibility of bending the copper tubing. 3) You will need an acid/vapor PPE mask as you will be in close proximity of the OA vapor. There is no getting around this. I currently use a 3M 7502 mask with organic vapor/ acid gas filters – $13.99 on Ebay, and non vented safety goggles – $7.99 Ebay. The mask worked great and I never even got a whiff while standing behind the hive administering the OA vapor. (more on this later)

Some of the nice things about the unit are: 1) Its speed. I usually just stood there behind the hive for 20 seconds and let it do its thing. 2) The plume of vapor into the hive is thick and sudden. The bees don’t have the “warning time” they did with pan type vaporizers to start fanning. Bang, it’s in there and done. Most of the hives didn’t object any more than they did with the pan vaporizer but a couple did. All hives settled down soon afterwards. 3) The almost constant 230C temperature ensures the OA is properly sublimated. I always suspected the gradual warming of the OA with the pan vaporizers may have wasted some of the OA as it was evaporated, boiled off, or was otherwise consumed instead of sublimated thus diminishing the dose. The ProVap110 ensures the OA always hits the pan at exactly 230C. 4) I often lose my biggest and strongest hives over the winter. I’ve always suspected it might be related to inadequate OA treatment reaching the upper boxes. Now I can treat the hive via a 1/4″ hole placed anywhere, in any box, instead of just underneath the hive. And don’t worry about drilling 1/4″ holes in your woodenware, the bees will propolize it soon enough or you can use a golf tee or dowel rod to plug. 5) It would be nice to have a half dozen of the “caps.” to prepare in advance. It’s not essential; that’s just my OCD speaking.

General comments: Most efficient use would necessitate a planned layout of the hives in the bee yard. If you scatter your hives around here and there you’ll waste time in transit. I have basically three different zones in my home yard. This meant driving the truck to three different positions and repositioning the drop cord each time. I think keeping your hives within a 100 foot radius and using a 100 foot drop cord might be ideal. Having plenty of IPM boards available is also a great time saver as transferring them hive to hive is a time waster. Luckily I have plenty to use in case of a severe winter but others may not. The hives with solid bottom boards were easiest to treat.

Now, here’s an interesting thing: The visible escaping particulate using the ProVap110 was noticeably less than when using pan type vaporizers. I can’t really account for why this is other than the bees don’t have the 2 – 4 minutes to start fanning before the deed is done. I actually used the ProVap110 in the first two hives and thought, “Did it work?” So I loaded the ProVap110, held it downwind, and flipped it to see if it was sublimating the OA. Yes, it was working and it’s done in about 20 seconds. If you look at the video, at the end the guy does exactly this and you can see how thick the plume is and how fast it comes out. Anyway, my point is, there appears to be less particulate escaping the hive than with pan vaporizers – and that’s a good thing!

Cleanup is a breeze. A little water to wash out the areas where the OA comes in contact was quick and easy. The unit itself cools off quickly when unplugged which is good and bad. Good for safety once you are done but moving into different bee yard zones meant having to wait the 2 – 3 minutes for the unit to return to operating temperature. I’m convinced I can shave 30 minutes off my first effort implementing some of the changes mentioned above.

I am satisfied with the unit over the pan type vaporizers for a few reasons: time efficiency, proper sublimation, flexibility in selecting placement of the area the OA is administered, and ease of use. I’d recommend it to anyone that starts to feel that pan-type vaporizing is taking too much of their bee management time that could be better spent more productively.

Addendum August 31st, 2017: After having used the ProVap100 for multiple yard treatments I thought I’d comment on a couple items I hedged on in my first review (above). First, use of multiple extension cords makes no noticeable difference in either warm up time or time to sublimate the oxalic acid. I am now using two fifty foot extensions cords and I get the same excellent performance as with one. Second, After having a problem with my gas powered generator I purchased an inexpensive 400 watt inverter at my local Harbor Freight store for ~ $23.00 USD. Using this as my power source the ProVap100 performed again without any degrading of performance. At $23.00 versus what I paid for the gas powered generator I’d opt for the inverter first unless there was an issue with access to the bee yard. Third, Thus far this year I have not lost my biggest hives post nectar flow and during the Varroa buildup as I have in previous years. I am unable to say that positive outcome is a result of the ProVap100 but I suspect it is a contributing factor. I remain very happy with the unit and from emails and messages I have received from people that have also purchased one they are likewise happy with the efficiency and ease of use of this unit.

 

Time for Midlands Swarm Traps

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beekeeping, management, swarms

Using waxed nuc boxes this year for swarm traps.

Tending bees is a lesson in looking forward.

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beekeeping, management

Let’s say you were going to open a new business and wanted to hit the market with a bang on day one of shopping season – say black Friday or whatever. You’d have to start preparing for that day ahead of time. How far ahead of time? You really don’t want to hire employees too soon and not have anything for them to do for months. Instead you want to hire them just enough ahead of time to get them oriented to their new jobs, well trained, and ready to service mobs of customers exactly on your Grand Opening date.

The same applies to your honey bees. Grand Opening date is the day the nectar flow begins in earnest. We can never know exactly when that date is as nature deals us a slightly different set of circumstances each year. But seasoned beekeepers in your area can give you a good estimate of the date nectar flow begins and ends in your area. Your job, as the beekeeper, is to have a full staff of employees ready and trained to gather that nectar starting on day one of the season. You’ll also have to worry about employee retention and expansion over the course of the nectar season. Finally, you’ll have to curb hiring as the season diminishes so that you’re not squandering resources on employees that will never gather nectar.

Here in the Midlands of South Carolina most seasoned beekeepers recognize the beginning of the spring nectar flow as April 1st. This year it appears to be running ahead of schedule. For the purpose of this article we’ll say April 1st and you can adjust for your location and observations. A 3 week old foraging bee available to work on April 1st has already graduated through the various stages of nurse bee, house bee, wax producer, etc. Prior to that she spent 21 days as an egg, larva, and pupae. So exactly when did you need your queen to lay that egg to produce that foraging bee available for work on April 1st? Bee math tells us she needed to lay that egg on approximately February 14. This is easy to remember as it is Nicolai Nasonov’s birthday. But wait, if the queen lays 1,200 eggs per day and does so on February 14 that results in 1,200 foraging bees on April 1st – but we want more than 1,200 bees don’t we? No worries, she didn’t go from 0 to 1,200 in one day. Instead, she’s been increasing her output since the winter solstice. But my point is February is critical for the beekeeper to stimulate production if he or she wants to have a full staff of foraging bees to get the job done in a manner that produces excess honey.

The same math can be used to determine when to start curtailing hiring new employees (bees) during the nectar flow. Our Midlands nectar flow ends approximately June 1st – a brief 2 months from its start date. An egg laid on April 19th will become a foraging bee on June 1st. That’s simply too late to contribute to nectar gathering. But that same bee will eat as much as any other bee in the hive and required the same amount of nutrition and work to create. Now here’s the dilemma, that colony is going to be in full tilt workaholic mode during the course of the nectar flow. It’s all hands on deck and as long as nectar is coming through the front door the queen will continue to lay eggs. The colony will continue to build and build bees because they have all the resources to do so. And the summer solstice isn’t until June 21st so that’s of no help. If you’re still hiring bees after April 19th you’re setting yourself up for having to feed those non-productive bees during the remainder of the nectar flow as well as the coming summer dearth. That means less excess honey for you.

What’s a beekeeper to do? A couple ideas might be to use that nectar flow time after April 19th to create a brood break by caging the queen. This would benefit the colony by reducing mite count via a brood break. A second option might be re-queening your hive allowing for a brood break. Moving your queen across the yard and allowing them to requeen would provide an almost perfect 25 or so days with out new brood. (Your queen across the yard is your failsafe.) Another option might be to “steal” frames of brood and get an early start on summer splits. The number of cells in a deep frame is around 7,000 although there is honey and pollen taking up some of the cells. Nevertheless, taking a frame of open brood, a frame of closed brood, and a frame of honey will hardly set an expanding colony back much and should result in an increase in your honey yield due to fewer mouths to feed. Plus you’ll get another colony, a new queen, a break in mite production, and a backup colony should anything go wrong in the fall. And with the nectar flow still in progress everything goes easier – wait until dearth comes and the same tasks will be much more difficult.

I’ll end here. Tending bees is a lesson in looking forward.

Buzzkill: Will America’s Bees Survive? | DiscoverMagazine.com

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beekeeping, honey bee biology, pests

The science and politics of saving America’s bees gets messy. And the bees continue to die.

Source: Buzzkill: Will America’s Bees Survive? | DiscoverMagazine.com

Darwin’s difficulty with the evolution of Honeybees

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beekeeping

Source: The Mountain

In beekeeping there are some colony behaviours that we learn about and adapt to, but what is it that makes bees behave in certain ways, some things can be explained others are still a puzzle even to Darwin!

As a beekeeper the evolution of the honeybee can help to explain certain behaviour within the colony. The following attempts to discuss the latest situation.

‘In the Origin of Species, Darwin discussed several challenges that worker insects presented to his theory of natural selection. Complex instincts such as building of combs of hexagonal cells were one problem and were explained by showing plausible intermediate stages. A more serious challenge was posed by the multiple worker castes seen in many ants. How could sterile individuals continue to evolve?  Some modern commentaries on Darwin and insect workers seem to be cases of present interests interfering with the interpretation of the past. From a modern perspective, the evolution of a worker caste, and its corollary altruism, are evolutionary puzzles inasmuch as natural selection normally favors greater, not lesser, individual reproduction.’ Darwin’s special difficulty: the evolution of “neuter insects” and current theory. Ratnieks et al

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The following is taken mostly from The Buzz about Bees by Jurgen Tautz and explains the kinships of worker bee sisters and half sisters and the drones. It helps to get a feeling about how the bees might behave in certain situations.

William D Hamilton explains how worker bees are more closely related to their sisters than to their own sons which would explain why they are happy to raise their sisters….until we consider the fact that the queen mates with about 13 drones when it becomes apparent that workers are less related to their half sisters than they are to their own sons…Hamilton’s detail is below with my summary at the end.

The unusual situation of kinship in the honeybee colony may be better understood in terms of a concept that has become popular through the work of the English biologist, William D. Hamilton (1936–2000).

The essence of Hamilton’s idea is as follows: particular genes localized at the same place in particular organisms, and which influence the same character, are called alleles. Alleles can occur in different forms, and are the basis for variability in the gene. The alleles are not only passed directly onto the offspring, but copies of these exist also in their siblings and their children, cousins, aunts, uncles, and entire families.

The likelihood of finding the same allele in individuals decreases the more remote the kinship of an individual is to the source. The carrier in which the allele resides is of little consequence for the success a single allele has in spreading as a competing allele in a population.

A behavior in relatives that contributes to rearing the young, for example, can be of advantage to both the supporters and their alleles, even if the carriers have no offspring of their own. Such a sacrifice is then not a disadvantage, if the alleles occur sufficiently frequently in the family.

Kinship selection, a theory developed by John Maynard Smith (1920–2004) and William D. Hamilton, based on the distribution of alleles in groups of related organisms, has clear consequences for the appearance of cooperative, or in extreme cases, “altruistic” behavior in animals.

This theory offers an explanation for single organisms that, like honeybees, have crossed the threshold from “loners” to social beings in the course of their evolution. (Or does it?)

Alleles that are most successful in the branching family network exist “selfishly” at the expense of other alleles. The vision that alleles behave selfishly, and aim only to set as many copies of themselves as possible in the world, has been convincingly explained by Richard Dawkins (1941–), in his book “The selfish gene”.

To an observer, alleles appear as selfishly behaving single elements, exhibiting what could almost be termed a “propagative drive” in honeybees.

Honeybees have, like all other Hymenoptera, and many other insect species that do not form colonies, an unusual mechanism for determining the gender of the adults.

Bees from unfertilized eggs have a single set of chromosomes, the haploid chromosome state.

Bees from fertilized eggs have two sets of chromosomes, the diploid state.

Honeybees possess a single gene for the determination of gender, which can appear in different alleles. An individual that is homozygous for this gene (the alleles are identical), which has to be the case for all haploid individuals (they possess only a single allele), will develop into a male.

An individual that is heterozygous for this gene (all the alleles are different) develops into a female.

A diploid individual homozygous for the sex gene, which very seldom occurs, is a diploid drone, and is usually killed by the workers in the larval stage.

This method of determining the sexes through the number of chromosome sets, or haplo-diploidy, has unusual consequences:

• Males have no fathers, because they come from unfertilized eggs.

It follows that males have no sons, at the most, grandsons.

• Should a male and a female produce daughters, these daughters will share more common alleles than they would with their own children.

Approaching the concept in small steps allows a better understanding of these curious circumstances:

• In 1969, the French bio-mathematician Gustav Malecot (1911–1998) defined genetic kinships as “r”, which is the average probability that a particular allele selected from an individual will also be found in a particular individual to which it is related.

• The value “r” is of biological significance from the point of view of the gene “spender”, because this defines the direction of the gene flow.

• All the alleles of the haploid father will certainly be passed onto each daughter. The probability of occurrence of the father’s alleles in the daughters is 100%, or, expressed differently, r=1.0.

The father will therefore find every one of his alleles again in every daughter.

• The statistical probability that the same alleles of the diploid mother will be found in her daughters lies at 50%, or r=0.5, because a mother contributes exactly half of her alleles to each of her egg cells.

A mother will therefore find, on average, half of her alleles again in a particular daughter.

• The probability that the same alleles will be found in a comparison between full sisters is given by a summary of factors relating to the father and the mother: half of the genome of a female bee comes from the father, and is identical in all full sisters.

Mathematically expressed, this means that 100% of 50% of the sisters’ genes are identical.

The other half of the genome comes from the mother, and has only a 50% probability of being identical in the sisters, because for each gene the mother has one of two possibly different alleles to offer.

In terms of the entire genome, this means 50% of 50%, or 25% are identical.

If one now adds up the values that come from the alleles of the father and the mother, and compares the sisters to one another, one gets 50%+25%=75%, or r=0.75 genetic kinship.

Honeybee sisters therefore share a statistical average of three quarters of their alleles.

In reality, this value swings between 50% of common alleles (only the alleles from the fathers are inherited), and 100% (alleles from both the father and the mother are the same).

Cloned animals are 100% genetically identical; their degree of genetic kinship is r=1.0.

Human children are 50% identical to their parents; here, the degree of genetic kinship amounts to r=0.5.

Honeybees, with their r=0.75, lie between cloned animals and humans.

From this perspective, the best thing that a female bee can do to propagate her genes is to renounce having her own children, and instead help her mother to bring as many sisters into the world as possible.

In order to propagate their alleles, the sterile workers should cooperatively support each other. This is exactly what happens in bee colonies, although the situation is a little more complex.

A queen on her nuptial flight usually pairs with about 13 drones, and their sperm fertilizes the eggs that will later develop into females. The workers in a bee colony all have the same mother, because they all stem from the same queen, but are from many fathers.

Graph by Glyn Davies of Newton Abbott BKA

Workers that are produced from the sperm of the same drone are full sisters. They are half sisters to those that have different fathers.

Full sisters share more common alleles than do half sisters, so they should support the half sisters less than they do other full sisters.

A complex game of cooperation between the full sisters, and conflict between the full sister groups would be expected if bees supported their closest kin, although an interaction of this kind would depend on them being able to distinguish between full and half sisters.

Bees can determine a great deal about their conspecifics through their sense of smell. The decision of whether or not a bee that wishes to enter the hive belongs to the colony has fundamental importance. This check is undertaken by guard bees at the entrance to the hive, which can smell a newcomer from a distance, and touch her with their antennae when she lands.

Chemo-sensitive sensilla in their antennae enable them to establish whether she belongs to the nest, or is a stranger.

If the odor signals “stranger”, the newcomer will be aggressively chased off. She does, though, have the possibility of being granted entrance if she bribes the guard bees with a drop of nectar.

Conditioning experiments have shown that bees are able to distinguish full sisters from half sisters by the odor of their cuticle, the thin wax layer that covers all insects and protects them from dehydration. Do they use this ability, and if so, when would it be significant in terms of kin selection?

For kin selection, odor identification would be important when new reproductive animals are being reared, because the queens and the drones have a propagative future.

The rearing of a new queen will set the genomic direction for the new colony, and here there is a high potential for conflict between the different groups of full sisters in the nest.

We know virtually nothing about how a colony decides who the new queen will be.

Do subtle conflicts and contests take place between the half sisters that we have not recognized? Do the still generally unknown, but often reported behavior patterns of workers, young queens, and drones on nuptial flights play a role?

Much of this is still a complete puzzle.

An additional area of potential conflict occurs when the workers themselves begin laying eggs.

In European bees, this happens at a rate of 1 in 1,000. Such eggs are unfertilized, and result in haploid drones. In such a colony, therefore, drones can arise that stem from the queen, and have a degree of kinship with her of r=0.5.

Drones that stem from workers have a degree of kinship of r=0.5 with their worker mothers. The degree of kinship between a worker and her brother is r=0.25, and this value is independent of the number of queen pairings, because the mother passes her own genes onto her sons in the unfertilized eggs.

Things get really complicated when one calculates the degree of kinship between a worker and her nephew, the son of one of her sisters. The values that one obtains here are dependent on the number of pairings of the queen on her nuptial flight. If only one pairing took place, the worker would have a kinship of r=0.375 with the sons of her sisters (and in this case, all the workers would be full sisters).

With two possible fathers, the degree of kinship to the nephews sinks to r=0.1875, which is below the kinship of r=0.25 shared with brothers.

If the queen had mated ten times, a kinship of r=0.15 between workers and their nephews results.

Graph by Glyn Davies of Newton Abbott BKA

Purely theoretically then, and considering the usually typical multiple mating of the queen, it would be of genetic advantage to the workers to kill the sons of their sisters, but not their brothers, and on no account their sons, with a kinship of r=0.5.

Workers should therefore suppress nephews that are genetically remote from them, and workers eat the eggs of other workers. They should protect their own eggs, and those of their full sisters, while destroying those of their half sisters, but it is still not clear whether bees can distinguish between the eggs of their full and half sisters.

Workers could also “make sure”, and simply eat up all the eggs that have not come from the queen.

The quantitative determination of the genetic kinship between the members of a bee colony provides the basis for an ambitious theory.

The degree of kinship “r” that is calculated is a statistical average that lies between widely separated extremes.

When a honeybee meets another bee, pupa, larva, or a different egg, she is not confronted with a statistical mean for “r”, but with a concrete single “r”. Can a honeybee determine this value when meeting another individual?

The destruction of haploid drone eggs by the workers shows that they can distinguish between the eggs of the queen and their sisters. The chance distribution of the alleles will, however, lead to situations in which a worker could come across a haploid egg from the queen with which she has nothing genetically in common, or an egg of one of her sisters with which she shares the maximum possible number of alleles.

For the theory to hold, it is not the origin of the egg that determines the action a worker should take, but the nature of the genome.

Just how well honeybees are in reality able to recognize, and use the degrees of kinship still needs to be demonstrated.

In the case of the destruction of worker eggs by workers, there is a simpler explanation: the consumption of eggs could be a purely hygienic precaution.

Very few of the larvae from worker bees molt, and embryonic development either does not start, or the embryo dies. In contrast to determining the degree of genetic similarity, worker bees are faced with the far simpler task of distinguishing dead from living eggs. It is also highly likely that eggs from the queen can be recognized by a protective odor provided by the queen when she lays these. Many questions remain unanswered.

The determination of sex in the form of haplo-diploidy in the Hymenoptera brought about the evolution of superorganisms, and provides an explanation for the change from living as an individual, through living in associations, to sociality and eusociality.

The reality of the presently living superorganisms does not support the theory that kinship alone is the explanation of bee biology. The difficulty of the enormous range of the r-value around the statistical mean has already been mentioned. This becomes even more complicated if the multiple pairing of the queen is taken into consideration when calculating the degrees of kinship.

Hamilton’s quantitative ideas would be valid only if all bees in a colony are from one mother and one father, but because many fathers leave their traces in a bee colony, this does not apply to the bee colonies that we find today.

The workers of a colony are less genetically similar amongst themselves than they would be to their own daughters.

Perhaps we have, in the application of the theory of kinship selection to honeybees, a situation deserving T.H. Huxley’s (1825–1895) remark that “The great tragedy of science is the slaying of a beautiful hypothesis by an ugly fact”. The situation here, though, is not quite as severe. During the passage of evolution, kin selection and haplo-diploidy were needed for the bees, and other hymenopterans, to find their way to their superorganisms.

Hence, when establishing nests, sisters would help one another in raising the young, just as we find today in wasps. But what keeps honeybees still at this level today, if kinship selection is no longer a significant basis?

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A bit more about haploid and diploid:

This diagram is from a lecture given by Gudran Koeniger at the National Honey Show 2014 entitled “Mating Biology of Honeybees. DCA’s – A Natural Strategy To Avoid In-breeding”

In this lecture Gudran also shows results of findings at Drone Congregation Areas, DCA in Austria where drones from 230 colonies were found with over a third of these being the only drone from a particular hive. This demonstrates that the best way to avoid brother and sister mating is to mate outside the hive and at a DCA with drones from many different colonies.

Gudran also mentions the sperm distribution as can be seen in the graph below such that when a queen mates she keeps more sperm from the first drone than the second and so on, hence creating a colony that has an imbalance of groups full sisters. Maybe this imbalance is what influences the choice of new queen or indeed if the colony ever becomes queenless and workers start to lay and raise their own drones.

Some related research notes:

1. There is some evidence that bees will selectively confine half-sister queens over super-sister queens, one of the best examples yet of potential genetic control of the final queen. Bee Culture June 2011.
2. “Honeybee queens are not reared at random but are preferentially reared from “royal” subfamilies, which have extremely low frequencies in the colony’s worker force but a high frequency in the queens reared.” DNA Analysis of Bees in a Mature Colony (BUT NOW BLUE BLOODED FAMILIES!:- by Robin Moritz, Peter Neumann et al 2005.)

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In summary, honeybees still pose a problem for the theory of evolution inasmuch as natural selection normally favors greater, not lesser, individual reproduction. We also see that kinship shows us that sister workers are 75% related which means that they are more related to each other than to their own sons and hence more inclined to raise sisters. However, the queen mates with on average 13 drones and this means that half sisters are less related to another half sister than to their own sons. For honeybees at least then there is still a social harmony puzzle.

Incidentally for bumblebees and wasps kinship can explain nicely how harmony exists as their queen only mates once. But even with bumblebees we see intra colony trouble when the queen switches to drone laying as the workers then prefer to raise their own sons than their brothers. (Goulson)

It is unclear how a queen is selected or indeed the egg or larvae that will become the queen. The logic is that sisters will prefer a queen from their own sister over that of a half sister. Maybe this is the reason that many queens are produced. But the research by Robin Moritz, Peter Neumann et al 2005 would suggest otherwise (see above).

It would be interesting to note how long after the introduction of an unrelated queen to a nuc that the laying of drones ( by the new queen) starts. The obvious logic would be that this would only occur once the majority of the bees in the colony are daughters of the new queen. Yet we see a colony with an unrelated queen that has not mated successfully and hence a drone laying queen has her offspring, her sons reared. Kinship can only be a part of the story of social harmony.

In the scenario above kinship plays no part in the acceptance of a new queen and her sons.

Is it then that the queen pheromone plays a significant part in this harmony?

What we observe is that when a virgin queen emerges she is still immature and the worker bees may recognise her as not being a worker, but they don’t recognise her as a ‘queen’. Over several days the virgin queen starts to mature and becomes ready to mate. She then mates and spends a further few days completing her maturity before starting to lay eggs.

When the workers recognise her as their queen is still unclear, however, it is probably shortly after she has emerged from the pupal cell and become the only queen in the colony. What is also apparent is that her brother drones within the hive treat her as a worker, they don’t try to mate with her. This might be because she doesn’t emit a mating pheromone at this stage. It is highly likely that drones will only mate on the wing and when they detect the queen mating signal (pheromones) as it is known that a brother can and does mate with his sister queen hence the diploid male eggs that the workers reject.

Further study of the drone laying worker scenario might give us a further lead into what it is that bonds the workers of the colony.

It remains that honeybees as individuals don’t follow Darwin’s theory of evolution…

Darwin found a solution that solved these challenging difficulties. The problem depicted would be significantly reduced if one accepted that selection could act not only on the individual, but also on the entire colony. Seen in this light, entire colonies would compete for the largest number of daughter colonies that were reproduced, not of individual bees. Modern evolutionary biology now includes the concept of colony evolution in the term group selection. Just why it is that the individual workers of honeybees, and their relatives, bumblebees, wasps, and ants, do not compete against each other within the colony remains unsettled. Nevertheless, it is precisely this renunciation by the workers of producing their own offspring that the honeybees have used as successful strategy to propagate their own genome.

Observation and experience shows that there are colonies that swarm hardly ever, some that supersede their queen hence never swarming and those that seem to swarm several times a season.

Is it really these latter colonies that are the secret to the evolution of the honeybee?

Beekeepers recognise that swarming is how the colony propagates, but we work with it. To get an excess of honey we need an excess of bees and to this end queen breeders will often look to keep ‘swarminess’ to a minimum. It follows that if all colonies behave in a way to only supersede their queen when she gets old, honeybees would die out.

Where does altruism begin and where does it end?

Source: The Mountain

The Mountain

In beekeeping there are some colony behaviours that we learn about and adapt to, but what is it that makes bees behave in certain ways, some things can be explained others are still a puzzle even to Darwin!

As a beekeeper the evolution of the honeybee can help to explain certain behaviour within the colony. The following attempts to discuss the latest situation.

‘In the Origin of Species, Darwin discussed several challenges that worker insects presented to his theory of natural selection. Complex instincts such as building of combs of hexagonal cells were one problem and were explained by showing plausible intermediate stages. A more serious challenge was posed by the multiple worker castes seen in many ants. How could sterile individuals continue to evolve?  Some modern commentaries on Darwin and insect workers seem to be cases of present interests interfering with the interpretation of the past. From a modern…

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Lemon Honey Ginger Tea

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beekeeping, honey, recipe

Source: Honey Lemon Ginger Tea

Woowee! Grad school has been kicking my booty lately (that kind of rhymes and I’m into it). I have definitely been feeling the stress of writing papers, assignments, and the black death that it is organic chemistry. I am a faithful coffee drinker, we’ve been going steady for about 7 years now and I don’t see us breaking up anytime soon, however, when I’m feeling stressed my nerves can’t quite take the added caffeine in my system. So I’ve been drinking this lemon honey ginger tea A LOT. Now I know you can go to the store and buy lemon honey ginger tea, but it honestly just tastes like a dried bag of nastiness and no one has time for that. Plus this way you get the added benefits of fresh ginger and lemon, and you can make sure there aren’t any other sneaky ingredients being added.

This is also a great drink to make if you’re feeling under the weather… hello flu season! If you can, buy raw local honey. Buying local honey may actually be able to help ward off allergies. Some think that when you ingest the honey you are also ingesting small amounts of pollen, and over time this can help to make you less sensitive to pollen. Ginger has a long history of being used medicinally to help with digestion and immunity. Lemon contains vitamin C, vitamin B-6 and flavonoids, among other immunity boosting nutrients.

Ingredients

• 1 teaspoon grated ginger (no need to peel it)
• 2 teaspoons fresh lemon juice
• 1 teaspoon raw local honey (you can skip the honey if you are avoiding sugar)

Add all the ingredients to a pot with a mugs worth of water. Let the ingredients simmer on low for 5-7 minutes. Strain the water into your favorite cup and enjoy! You may need to play around with the measurements until you reach your ideal tea.

Source: Lemon Honey Ginger Tea

Worker laying workers — The Apiarist

Tags

beekeeping, honey bee biology

Source: via Worker laying workers — The Apiarist

A few months ago I wrote about problems encountered with laying workers, and ways to overcome those problems. Laying workers occur when a colony lacks sufficient open brood pheromone to suppress egg laying by the workers. One solution, though not one I favour, is to repeatedly add frames of open brood to suppress egg laying and then either add a queen, or allow the colony to raise their own.

The article was titled ‘drone laying workers’ and, in the comments, Tim Foden correctly pointed out that the prefix ‘drone’ was probably superfluous. Since the workers were unmated they would only be able to lay haploid eggs which would inevitably develop into drones.

Without intervention a laying worker colony is doomed. However, drones from a laying worker colony are fertile. Therefore, from an evolutionary perspective you could consider the rearing of drones is a last-gasp effort to pass on some of the genes to successive generations.

But … there’s always a but

The Cape honey bee (Apis mellifera capensis) is a subspecies usually restricted to the Western Cape region of South Africa. Laying workers of Cape honey bees can lay eggs that develop into workers (or queens). Since these ‘mother’ workers are unmated and their resulting progeny workers are diploid, this takes some genetic trickery. This mechanism is snappily titled thelytokous parthenogenesis.

Parthenogenesis is most simply defined as reproduction without fertilisation. Thelytoky is derived from the Greek thelos, meaning ‘female’, and tokos, meaning ‘birth’. The next time you’re asked to define thelytokous parthenogenesis in the pub quiz your team will have the edge – it means giving birth to females without reproduction. The female progeny capensis workers produce can be reared as workers – essentially clones of their mothers – or, with a change in diet for the early larvae, queens.

The genetic trickery involves the haploid pronucleus of the egg fusing with one of the polar bodies that are generated during oogenesis (egg production). Polar bodies are small haploid cells that bud off during ovum development. Fusion of the two haploid cells creates a diploid, which can go on to become a female bee.

No laying worker problems then … ?

Quite the opposite. You’d think that by encouraging this type of activity in Cape honey bees your laying worker problems would be a thing of the past. In fact, your problems become a thing of the future. Laying workers of capensis are socially parasitic. They invade – through drifting for example – unrelated neighbouring colonies, such as those of Apis mellifera scutellata (another subspecies, the African honey bee). Once there, the eggs they lay are reared by the new colony, but the resulting workers do not contribute to foraging or other hive activities. Instead they also become laying workers (worker laying workers that is ), eventually leading to the collapse of the host colony.

Capensis has been spread widely from its original range through migratory beekeeping, leading to large-scale colony losses and significant economic impact to the beekeeping industry in regions of South Africa distant from the Western Cape. Capensis also hybridises with scutellata in areas where their ranges overlap.

Divide and conquer

Honey bees are social insects. Cape honey bees, for all their unsociable parasitic activities are also social. However, their unsociable activities aren’t restricted to parasitism. They also exhibit a trait called worker policing. A Cape honey bee colony might contain several laying workers. The workers they rear are able to discriminate between eggs laid by their ‘mother’ and those laid by her half-sisters – effectively their aunts – in the same hive. Once they detect a foreign egg, they either eject it or eat it.

This worker policing can lead to sub-division of the hive, with territories being established in separate parts of the hive, each containing genetically clonal populations of laying workers. However, unless the colony rears a new queen its long-term prospects are very limited. The prodigious egg-laying ability of a queen far outstrips that of even multiple laying workers, meaning the colony – and all its sub-divisions – will eventually dwindle and be lost.

Worker policing is an interesting phenomenon and has some relevance to queen rearing and larval selection which I’ll address later in the season.

Pedantically speaking … and wind

Laying workers colonies in the UK characteristically rear large numbers of drones. This is why Tim Foden correctly commented that the prefix ‘drone’ is superfluous. However, to be absolutely pedantic it is needed. This is because, irrespective of the strain of bee, up to 1% of eggs laid by laying workers are diploid. All bees exhibit thelytokous parthenogenesis but it’s only in capensis the trait is common.

Why is it only in capensis that this trait is common? It’s been suggested the selection for thelytokous parthenogenesis is due to the strong winds that occur in the southern region of South Africa in which capensis is the native honey bee. As a consequence of this, queens are often lost on mating flights, rendering the colony queenless. Without “worker laying workers”  – or, more correctly, diploid laying workers from which new queens can be raised – colonies would be doomed.

Capensis queen mating flights have been documented at wind speeds in excess of 30 mph … another adaptation to the climate of the region. In contrast, scutellata queens, from more northerly regions in South Africa won’t go on mating flights if the wind speed exceeds ~12 mph.

Cape honey bees are wonderfully well adapted to the Western Cape Fynbos region of South Africa. They are the strain beekeepers choose to use for honey production and pollination in an area with huge biodiversity and ~6000 endemic plant species. In trials using alfalfa, capensis-pollinated plants set twice as much seed as those pollinated by scutellata. This suggests they are particularly thorough plant ‘visitors’, a conclusion supported by their ability to collect pollen which was also twice that of scutellata. They have additional unique characteristics. In a publication pre-dating the introduction of Varroa to South Africa, Hepburn and Guillarmod (PDF) describe how readily capensis absconds in summer and migrates in winter, both characteristics the reflect adaptation to the climate and the regular wildfires in the region, and not seen in other strains of bees.

Finally, in much the same way that moving capensis colonies elsewhere has caused problems, the introduction of American foulbrood to the region in 2008 (again through beekeeper activity) has resulted in the loss of 40% of Cape honey bees.

via Worker laying workers — The Apiarist

This Cat Don’t Eat Honey

Tags

beekeeping, honey

Humans can taste one drop of sucrose (table sugar) diluted in 150 parts water. A honey bee outranks our sugar sensitivity six-times over: about one part in a thousand and the bee is on it. What about Puff, the cat? Puff doesn’t jump on command nor does she care much for honey. Why do cats […]

via This Cat Don’t Eat Honey — Bad Beekeeping Blog

Life can’t always be honey

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beekeeping

Mrs Apis Mellifera

Pepper’s colony had eaten their first block of winter fondant. The hive had lost weight and it was possible to heft the boxes slightly off the stand. I stared down the hole of the crownboard into the dark abyss of empty honeycomb. There was no sign of activity. Then a single worker crawled up a wall and stopped a few inches beneath the crownboard. She stared back as I slowly lowered a new block of fondant over the hole.

The neighbouring hive belonging to Pepper’s daughter, Peppermint, had become heavier over winter. The workers seemed to have made good use of the milder days to find forage for stores. I lifted the insulation to discovera small crowd of beeshad found their way under the roof. They looked like young bees judging from their soft fuzzy thoraxes and perfectly shiny folded wings. They were too busy exploring the new space to…

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Our Hives They Are a-Changin’

Tags

beekeeping, honey bee biology, management, pests, varroa mites

Source: Our Hives They Are a-Changin’ by Bees with eeb

Aside from a single white morning this winter, we have had very little snow in Virginia. The weather is unusually warm and the bees seem to get a flying day once a week or so. I suspect the insect population will be robust this year, from small hive beetles to other assorted insects, due to our lack of cold weather. Soon the bees will start ramping up for spring, and I have been keeping an eye on the mite populations in Mars and Jupiter.

Mite Counts

I have screened bottom boards on Mars and Jupiter and count the mites every few days to determine the average daily mite drop. It is nice to track this number through the winter and have a sense of overall hive infestation. As you can see, the mites were high in Mars and had starting creeping up in Jupiter in mid-November. I did an oxalic acid dribble (OAD) on Nov 28 to knock them back. Oxalic acid is an organic compound found in rhubarb, spinach, and a number of other plants. Varroa mites react poorly to it, while the bees have a natural tolerance. I treated every hive in the apiary, which is recommended since the bees (and mites) will drift from hive to hive.

Right now the mite counts are low, around 1 to 2 mites per day. Soon, as the hives start to raise new workers, the mites will increase. Last year the uptick started in mid-February, so we’ll see when it starts changing this year.

The Varroa Problem

Speaking of our most dreaded pest, it appears that nationwide mites are starting to show some resistance to the most common synthetic pesticide, amitraz. I wouldn’t touch the stuff, but many commercial beekeepers use it. This could create some serious trouble for these outfits as well as crops such as almonds that heavily depend on bee pollination. The situation prompted Randy Oliver at Scientific Beekeeping to create a series of articles calling for a new focus on developing mite-resistant honey bees. Visit his articles by publication date page to see the series so far: part 1 through part 4 as of this posting.

The articles provide an in-depth look at why varroa mites are a problem and what we should do about it. Varroa is a vehicle for deformed wing virus (DMV) and other viruses, and as the mite population increases it spreads DMV and other ills among the bees. Colonies will typically collapse from these viruses before the mites become a serious threat.

The most interesting section for me is part 3, where Randy discusses why varroa mites and DMV are getting progressively more virulent. Since commercial beekeepers tend to use bees bred mainly for growth and honey production, the resistance to varroa and DMV in these bees is rather low. This coupled with the fact that hives are kept close to each other encourages more dangerous forms of the virus to develop. If a hive collapses quickly, other bees will rob it out and bring the mites and viruses back to their hives.

If beekeepers insisted on more mite-resistant stock, the virus would spread less quickly. Hive collapses would be more likely to occur during winter, rather than before it. Virus and mite transmission would then more frequently occur in swarms and splits, which would favor less virulent strains of the virus.

Randy does a better job explaining the science (which I may not have completely correct), the point is that the majority of beekeepers would need to insist on mite-resistant stock. In fact, according to Randy, that is exactly what happened in South Africa. The beekeepers there did not have the resources to purchase miticides when varroa arrived. After devastating losses for a few years, the bees recovered and now beekeepers in South Africa do not generally worry about varroa mites. We are unlikely to eliminate the mites, we need to evolve into a more stable relationship between honey bees and mites.

It is a great series, and I look forward to future installments. Check it out.

The Times They are a-Changin’

This 1964 song by Bob Dylan was the title track on the album of the same name. Dylan wrote the song to capture the feeling of change in the 60’s, and numerous bands have performed the song as a cover since then. In 1984, Steve Jobs recited the second verse of the song during the Apple shareholders meeting, where he famously unveiled the Macintosh computer.

For this post, the times are changing for me in a number of ways. Aside from the seasonal change of the bees as we move from winter to spring, I just left my prior job this past week after over five years with the company. My new position starts on Monday, February 6, so cross your fingers for me.

We can also hope that the sense of change will take hold in the beekeeping world. It is difficult for any one beekeeper, especially a hobby beekeeper, to make an impact on the genetics of North American honey bees. We need the major queen breeders to start selecting for mite resistance, something they tend not to do today. So keep your eyes open and don’t speak too soon, cause the times they are a-changing.

May you prosper and find honey.

Source: Our Hives They Are a-Changin’ by Bees with eeb