Biophysics of Insect Flight (N. Chari, Prasad Mukkavilli etc.)

N. Chari et al.

Table 4.7 Energetics of catabolism (Bio-molecules Oxidation)*

Type of biomolicules and metabolic pathway

Number of ATPs produced

Total energy (kJ)

Glucose and glycolysis and TCA cycle

26–38

780–1140

TAG (fatty acid C16)

129 + 16

4350

Proline (Oxidative Deamination, TCA)

450

*ATP upon hydrolysis yields 7.3 k cal/mol or 30.5 kJ/mol

*Insect spends 57 J of energy/gram body weight/hour of ﬂight

Myoﬁbrils are made up of ﬁne actin ﬁlaments (I-band) and thick myosin (A-

band) ﬁlaments. Actin ﬁlaments are isotropic and myosin ﬁlaments are anisotropic.

Troponin and tropomyosin proteins block the myosin head from coming in contact

with actin. Due to nerve impulse action, the calcium is released from the SR and this

in turn removes the TN-TM blocking. In the presence of ATP, the ATP hydrolysis

takes place leading to muscle contraction. Regulation of oscillatory contraction in

ﬂight muscle by troponin is rather well known. The sarcomere is the basic unit

of muscle contraction within the sarcomere, with the arrival of a nerve impulse at

Motor-end-plates (MEP), I-ﬁlaments slide against free ends of A-ﬁlaments leading

to muscle contraction. Flight muscles shorten by about 1%. The asynchronous ﬂight

muscles produce remarkable amounts of tension in muscle ﬁbres, in the presence of

large amounts of free calcium available in the cytoplasm in contrast to synchronous

muscles.

Insect ﬂight muscles are metabolically highly active such as they have more

of oxidative enzymes, mitochondrial respiration and aerobic capacity. Insect ﬂight

muscles depend on trehalose, proline and lipids as fuels in the metabolism. Carbo-

hydrates like trehalose and proteins like proline are used during short ﬂights. After

carbohydrates,aminoacidsalsoprovideamajorsourceofenergyinmanyinsectﬂight

muscles. Fatty acids are the fuels for long-duration and long-distance ﬂight. Locusts,

hawk moths and beetles depend on fatty oxidation. Fats are stored as triglycerides

and they are released as diglycerides. Fat produced double the energy as compared

to the unit weight of carbohydrate.

Since this book is dealing with the bio-aerodynamics of insect ﬂight, instead of

going into the details of metabolic pathways such as Glycolysis and Citric acid cycle,

the energetics of these pathways are given the form of Table 4.7.

Summary

The structure of the thorax including the ﬂying segments (pterothorax) and asso-

ciated wings and their morphology have been considered in detail. Wing venation,

which forms the supporting structural basis for the wing and its signiﬁcance in the

classiﬁcation of insect orders, has been elucidated. The wing is attached to the thorax

by a membranous basal area having sclerites, also known as pteralia, which along