Question 1

Draw the diagram of a sarcomere of skeletal muscle showing different regions.

Accepted Answer

A sarcomere is the basic contractile unit of skeletal muscle. It is the segment between two successive Z-lines. The diagram should show the Z-line, I-band (light band containing thin filaments), A-band (dark band containing thick filaments), H-zone (central region of A-band with only thick filaments), and M-line (middle line of sarcomere). Label each region clearly. — The sarcomere is composed of overlapping thick (myosin) and thin (actin) filaments. The Z-line anchors thin filaments, the I-band contains only thin filaments, the A-band contains thick filaments and overlapping thin filaments, the H-zone contains only thick filaments, and the M-line is the midline of the thick filaments. Drawing these with labels helps understand muscle contraction.

Question 2

Define sliding filament theory of muscle contraction.

Accepted Answer

The sliding filament theory states that muscle contraction occurs when thin (actin) filaments slide past thick (myosin) filaments, shortening the sarcomere without changing the length of the filaments themselves. This sliding is powered by the cyclic interaction of myosin heads with actin filaments, using ATP. — During contraction, the myosin heads bind to actin forming cross-bridges, pull the thin filaments towards the center of the sarcomere, and then detach to repeat the cycle. This causes the sarcomere to shorten, leading to muscle contraction.

Question 3

Describe the important steps in muscle contraction.

Accepted Answer

The important steps in muscle contraction are:
1. Nerve impulse reaches the neuromuscular junction and releases acetylcholine.
2. Acetylcholine triggers depolarization of the muscle fiber membrane, leading to release of Ca++ from the sarcoplasmic reticulum.
3. Ca++ binds to troponin, causing tropomyosin to move and expose myosin-binding sites on actin.
4. Myosin heads bind to actin forming cross-bridges.
5. Using energy from ATP hydrolysis, myosin heads pivot, pulling actin filaments towards the center of the sarcomere (power stroke).
6. ATP binds to myosin heads causing detachment from actin.
7. The cycle repeats as long as Ca++ and ATP are available, resulting in sliding of filaments and muscle contraction. — Muscle contraction is a cyclic process involving excitation, calcium release, cross-bridge formation, power stroke, and detachment. ATP is essential for both power stroke and detachment phases. The process ends when nerve stimulation stops and Ca++ is pumped back into the sarcoplasmic reticulum.

Question 4

Write true or false. If false change the statement so that it is true.
(a) Actin is present in thin filament
(b) H-zone of striated muscle fibre represents both thick and thin filaments.
(c) Human skeleton has 206 bones.
(d) There are 11 pairs of ribs in man.
(e) Sternum is present on the ventral side of the body.

Accepted Answer

(a) True. Actin is present in thin filament.
(b) False. H-zone of striated muscle fibre represents only thick filaments, not both thick and thin filaments.
(c) True. Human skeleton has 206 bones.
(d) False. There are 12 pairs of ribs in man.
(e) True. Sternum is present on the ventral (front) side of the body. — The H-zone contains only thick filaments, so statement (b) is false. Humans have 12 pairs of ribs, so (d) is false. Other statements are correct as given.

Question 5

Write the difference between :
(a) Actin and Myosin
(b) Red and White muscles
(c) Pectoral and Pelvic girdle

Accepted Answer

(a) Actin vs Myosin:
- Actin is a thin filament protein; Myosin is a thick filament protein.
- Actin has binding sites for myosin heads; Myosin has ATPase activity.

(b) Red vs White muscles:
- Red muscles have more myoglobin, rich blood supply, and are fatigue resistant.
- White muscles have less myoglobin, less blood supply, and fatigue quickly.

(c) Pectoral vs Pelvic girdle:
- Pectoral girdle supports the upper limbs and is more flexible.
- Pelvic girdle supports the lower limbs and is stronger and less flexible. — These differences highlight structural and functional distinctions between proteins, muscle types, and girdles related to their roles in movement and support.

Question 6

Match Column I with Column II :

|  Column I | Column II  |
| --- | --- |
|  (a) Smooth muscle | (i) Myoglobin  |
|  (b) Tropomyosin | (ii) Thin filament  |
|  (c) Red muscle | (iii) Sutures  |
|  (d) Skull | (iv) Involuntary  |

Accepted Answer

(a) Smooth muscle — (iv) Involuntary
(b) Tropomyosin — (ii) Thin filament
(c) Red muscle — (i) Myoglobin
(d) Skull — (iii) Sutures — Smooth muscle is involuntary; tropomyosin is a protein of thin filament; red muscle contains myoglobin; skull bones are joined by sutures.

Question 7

What are the different types of movements exhibited by the cells of human body?

Accepted Answer

The different types of movements exhibited by human body cells include:
- Amoeboid movement (e.g., white blood cells)
- Ciliary and flagellar movement (e.g., epithelial cells lining respiratory tract and sperm cells)
- Muscular contraction (e.g., skeletal muscle cells)
- Cytoplasmic streaming
- Cell division related movements — Cells move by various mechanisms depending on their type and function, such as amoeboid movement for immune response, ciliary movement for clearing mucus, and muscular contraction for locomotion.

Question 8

How do you distinguish between a skeletal muscle and a cardiac muscle?

Accepted Answer

Differences between skeletal and cardiac muscle:
- Skeletal muscle is voluntary; cardiac muscle is involuntary.
- Skeletal muscle fibers are long, cylindrical, multinucleated; cardiac muscle fibers are branched, shorter, and usually uninucleated.
- Skeletal muscle has no intercalated discs; cardiac muscle has intercalated discs.
- Skeletal muscle shows striations; cardiac muscle also shows striations but with branching.
- Skeletal muscle contracts rapidly and tires easily; cardiac muscle contracts rhythmically and does not tire. — These structural and functional differences help distinguish the two muscle types and relate to their roles in body movement and heart function.

Question 9

Name the type of joint between the following:-
(a) atlas/axis
(b) carpal/metacarpal of thumb
(c) between phalanges
(d) femur/acetabulum
(e) between cranial bones
(f) between pubic bones in the pelvic girdle

Accepted Answer

(a) Atlas/axis - Pivot joint
(b) Carpal/metacarpal of thumb - Saddle joint
(c) Between phalanges - Hinge joint
(d) Femur/acetabulum - Ball and socket joint
(e) Between cranial bones - Immovable (fibrous) joint (sutures)
(f) Between pubic bones in pelvic girdle - Cartilaginous joint (pubic symphysis) — Different joints allow different types of movement: pivot allows rotation, saddle allows biaxial movement, hinge allows flexion-extension, ball and socket allows multiaxial movement, sutures are immovable, and pubic symphysis allows slight movement.

Question 10

Fill in the blank spaces:
(a) All mammals (except a few) have _______ cervical vertebra.
(b) The number of phalanges in each limb of human is _______
(c) Thin filament of myofibril contains 2 'F' actins and two other proteins namely _______ and _______.
(d) In a muscle fibre Ca++ is stored in _______
(e) _______ and _______ pairs of ribs are called floating ribs.
(f) The human cranium is made of _______ bones.

Accepted Answer

(a) 7
(b) 14
(c) Tropomyosin and Troponin
(d) Sarcoplasmic reticulum
(e) 11th and 12th
(f) 8 — Most mammals have 7 cervical vertebrae; each human limb has 14 phalanges; thin filament contains tropomyosin and troponin along with F-actin; Ca++ is stored in sarcoplasmic reticulum; 11th and 12th ribs are floating ribs; human cranium is made of 8 bones.

Question 11

Which of the following is an example of locomotory movement in humans?

Accepted Answer

Walking — Locomotory movements are voluntary movements that result in a change of place or location. Walking is a typical example of locomotion in humans, whereas streaming of protoplasm, ciliary movement, and tentacle movement are other forms of movement but not locomotion in humans.

Question 12

In the context of movement and locomotion, which statement is correct?

Accepted Answer

All locomotions are movements but all movements are not locomotions — Locomotion is a subset of movement involving change in place or location and is voluntary. Therefore, all locomotions are movements, but not all movements (like ciliary movement or streaming of protoplasm) result in locomotion.

Question 13

Which type of movement is exhibited by macrophages and leucocytes in the human body?

Accepted Answer

Amoeboid movement — Macrophages and leucocytes exhibit amoeboid movement, which involves the formation of pseudopodia by streaming of protoplasm, similar to Amoeba.

Question 14

What role do cilia play in the human respiratory system?

Accepted Answer

Cilia in the trachea help remove dust particles and foreign substances inhaled with atmospheric air. — Ciliary movement occurs in the trachea where coordinated beating of cilia removes dust and foreign particles from inhaled air, protecting the respiratory tract.

Question 15

Explain the role of muscular movement in human locomotion.

Accepted Answer

Muscular movement involves contraction of muscles to move limbs, jaws, tongue, etc. It requires coordinated activity of muscular, skeletal, and neural systems and is essential for locomotion and other bodily movements. — Muscular movement is the contraction of muscle tissues under voluntary control, enabling movements such as walking, running, and posture changes. It involves skeletal muscles working with bones and nervous system coordination.

Locomotion and Movement

Locomotion and Movement — Study Notes

Introduction

17.1 Types of Movement

17.2 Muscle

Practice Questions — Locomotion and Movement

All 19 Chapters in Biology