Comprehensive Overview of Apis mellifera Drone Development, Biology, and Interaction with The Queen
Page: 1-17 (17)
Author: Lovleen Marwaha*
DOI: 10.2174/9789815179309123010003
PDF Price: $15
Abstract
The male honey bees, the reproductive caste of the colony, develop through
haploid/diploid parthenogenesis. The drones develop from haploid/ diploid unfertilized
eggs produced by parthenogenesis or from diploid fertilized eggs having identical sex
alleles, formed after sexual reproduction, with more probability when the queen honey
bee mates with the drones of the same hives. Therefore, two types of drone honey bees,
based on ploidy, are common in colonies, e.g. haploid or/and diploid. The number of
drone honey bees staying in the colony varies according to protein resources and the
strength of the worker honey bees. Generally, the haploid drone eggs/larvae laid by
workers are removed by the nurse bee due to cannibalism. The above-mentioned
eggs/larvae are marked with certain specific hormones that act as markers for
cannabalic removal of the same.
Further, the development of drones is influenced by colony temperature; hence overall
development can be completed within 24-25 days. The purpose of drone life is to
produce sperm and mate with the queen. The queen attracts the drone's honey bees
toward herself with pheromones 9-ODA, 9-HDA and 10 HDA. The drone number and
fertility depend upon the colony's environmental conditions, genomic possession and
available food in the colony. The specific chapter provides deep insight into the
development of drones, the biology of drones, the reproductive system, and the mating
behaviour of particular castes. Subsequent chapters highlight morphometric
characteristics of drones, development, mating, reproduction and artificial drone
production.
The Drone Honey Bee Morphometric Character
Page: 18-27 (10)
Author: Lovleen Marwaha*
DOI: 10.2174/9789815179309123010004
PDF Price: $15
Abstract
The Drone caste exhibits specific diagnostic morphometric characteristics
that facilitate its differentiation from other colony castes. Drone formation gets
completed in about 24-25 days, with the first ten days in an open cell and the final 14
days under capped conditions. Furthermore, the drone caps are convex in shape. The
Drone egg is measured about 1.49±0.12 (range 1.12–1.85) mm, the width is 0.35±0.02
(range 0.30–0.40) mm, and the volume is 0.10±0.02 (range 0.06–0.15) cubic mm. After
hatching for the first three days, the larval weight is 0.11 mg, the 7th-day-old larva is
120 mg, 11th-day-old larva reaches a weight of 350 mg. An adult has a mean body
length of about 1.5 cm. Further, the drone character varies as per ecological conditions,
species, genotype, and other environmental conditions.
The Development of the Drone Honey Bees: The Parthenogenesis
Page: 28-52 (25)
Author: Lovleen Marwaha*
DOI: 10.2174/9789815179309123010005
PDF Price: $15
Abstract
The drone honey bee develops from unfertilized or fertilized eggs depending
on the homozygosity of the sex alleles in inherited genomic content. In the honey bee
colony, if the polyandrous queen honey bee mates with the drone honey bees of the
neighbouring colonies, then the drones develop from the unfertilized eggs, confirming
the haploid parthenogenesis. However, the mating of the queen with the drones of the
same colony accelerates the feasibility of the development of drones, even from
fertilized eggs. In the above-mentioned former case, the drones are known as the
haploid drones, whereas in the latter case, the drones are referred to as the diploid
drones. Generally, the diploid drones are removed by worker honey bees by
recognizing the pheromones coated on the egg surface. The worker honey bees can
remarkably distinguish the queen's drone eggs and the workers acting as pseudo-queens’ drone eggs. The pseudo-queen develops if the colony is queen-less or the
queen is not carrying the required reproductive potential and pheromonal emission.
Drone development takes 24-25 days in total, with four distinct phases: egg, larval,
pupal, and adult, with durations of 3 days, six days, 15-16 days, and about 1-3 months,
respectively. The present chapter is attributed to the drone honey bees' developmental
synchronicity, haploid inheritance, parthenogenesis, and patrilineal genomic
contribution to the colony that influences colonial behaviour, productivity, life span,
immunity, and others.
The Pheromonal Profile of the Drone Honey Bees Apis mellifera: The Volatile Messengers
Page: 53-64 (12)
Author: Lovleen Marwaha*
DOI: 10.2174/9789815179309123010006
PDF Price: $15
Abstract
The drone honey bee produces volatile chemicals during developmental and
adult stages that facilitate chemical interaction between drone larvae and workers,
drone to drone, and drone to the queen. For example, the drone larvae solicit larval
food from nurse bees through chemical messengers; further, adult drones attract other
drones to drone congregation areas (DCA) through pheromones; the drones attract
queen honey bees to DCA through volatile chemicals. The mandibular drone gland
secretes volatile chemicals, a mixture of saturated, unsaturated, and methyl-branched
fatty acids. In the drone honey bee of Apis mellifera, about 18,600 olfactory poreplate
sensilla per antenna are associated with receptor neurons. The current chapter
highlights the role of chemical volatiles in Drone honey bee’s life and overall
influence.
The Mating and Reproduction in Apis Mellifera: The Role of Drone Honey Bee
Page: 65-83 (19)
Author: Lovleen Marwaha*
DOI: 10.2174/9789815179309123010007
PDF Price: $15
Abstract
Mating in honey bees occurs in the drone congeration area, where the queen
and drones gather for reproduction. Sexually mature drones from all colonies
congregate there, and the queen mates with multiple drones, increasing patrilinear
inheritance variation. The variation in genomic content results in specific colonial
behaviour, productivity, and strength. The current chapter discusses mating in honey
bee colonies.
Artificial Methods of Drone Rearing in Apis Mellifera and the Role of Drones in Quality Improvement
Page: 84-92 (9)
Author: Lovleen Marwaha*
DOI: 10.2174/9789815179309123010008
PDF Price: $15
Abstract
A few protocols are available for artificial drone rearing under controlled
conditions within or outside the honey bee colony. The initial development phase of the
drone development can be completed on royal jelly exclusively. Still, on worker jelly,
complete drop development can be carried out, as witnessed by a few researchers.
Sugars accelerate the drone's growth and support the passage of the drone through
certain embryonic and post-embryonic stages. The drones contribute patrilineal
genomic content that influences the overall strength of the colony, colonial behaviour,
productivity, and other characteristics. The current chapter is attributed to some
available artificial haploid/diploid drone-rearing methods and the influence of multiple
patrilineal genomic content contributions to other honey bees
Subject Index
Page: 93-96 (4)
Author: Lovleen Marwaha*
DOI: 10.2174/9789815179309123010009
PDF Price: $15
Introduction
This reference book is the definitive guide to drone honey bees. The book equips readers with all the knowledge they need to know about drone bee biology and development, their role in the colony and improving the health of their colony. The book starts by providing a detailed review of the development of drone honey bees, their biology, morphometric features, interaction with the Queen and the haploid parthenogenesis. The book then delves into the pheromone profile and mating behavior of drones. Further, the book describes artificial drone rearing techniques that facilitate healthy bee colony growth and increase apiculture productivity) including their genomic contributions). Key Features - 6 reader-friendly chapters that comprehensively present information about drone honey bees - Coverage about drone bee biology, including their physical morphology, development and behavior (including queen interactions) - Information about the role of drones in colonial organization and life-cycle events - Practical information that helps to improve bee colony health for research and apiculture The book is an essential primary reference on drone honey bees for biology and entomology students, academicians and researchers at all educational levels. Apiculturists, bee keeping enthusiasts, and general readers interested in honey bees can also benefit from the breadth of information presented.