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Defects in Signaling Pathway and Consequences | Zoology Optional Notes for UPSC PDF Download

Introduction

In light of the intricate nature of signal-transduction pathways, it is not surprising that occasional failures in these pathways can result in pathological or disease states. One such disease closely associated with defects in signal-transduction proteins is cancer, characterized by uncontrolled cell growth. The study of cancer, particularly those caused by viruses, has significantly contributed to our understanding of signal-transduction proteins and pathways.

1. Viral Oncogenes and the Example of Rous Sarcoma Virus:

  • Rous sarcoma virus, a retrovirus causing sarcoma in chickens, carries the oncogene v-src.
  • The v-src gene encodes a protein tyrosine kinase with SH2 and SH3 domains.
  • The v-Src protein, similar to c-Src, is an oncogene, while c-Src is a proto-oncogene.
  • Small differences in amino acid sequences lead to the oncogene being constitutively active.
  • The inactive conformation of c-Src involves intricate interactions between SH2, SH3, and kinase domains.

2. Activation Mechanisms of Src Protein:

  • Src can be activated by displacing the phosphotyrosine residue in the SH2 domain.
  • Phosphorylation on the tyrosine residue can be removed by a phosphatase.
  • The linker between the SH2 and kinase domain can be displaced by a polypeptide.
  • Src responds to distinct signals, exhibiting flexibility in its activation mechanism.

3. Mutation in Oncogenes and Biological Activity:

  • Despite more than 90% amino acid sequence identity, the viral oncogene exhibits different biological activity.
  • The C-terminal region of c-Src is replaced by a different stretch lacking a key tyrosine residue.
  • Mutated protein kinases, including Src, are identified as oncogenes.

4. Acquisition of Mutated Version by Rous Sarcoma Virus:

  • Infection allows a viral genome to pick up a host gene with a missing region encoding the last few amino acids.
  • The modified gene may confer a selective advantage, favoring viral growth upon introduction to a host cell.

5. Impaired GTPase Activity and Ras in Cancer:

  • Mutations in ras genes are common in human tumors.
  • Ras proteins cycle between GTP and GDP forms, and mutations often lead to impaired GTPase activity.
  • Ras protein remains constitutively active, contributing to cancer progression.

6. Protein Kinase Inhibitors as Anticancer Drugs:

  • Overactive protein kinases in cancer cells suggest potential targets for anticancer drugs.
  • In chronic myelogenous leukemia (CML), a specific inhibitor of the Bcr-Abl kinase has shown significant efficacy.
  • Clinical trials demonstrate more than 90% positive response, offering a distinct approach to cancer chemotherapy.
    Defects in Signaling Pathway and Consequences | Zoology Optional Notes for UPSC

Cholera Toxin and G-Protein Dysregulation

  • Cholera, an acute diarrheal disease, is caused by Vibrio cholera.
  • Choleragen, the cholera toxin, consists of B and A subunits.

Mechanism of Action:

  • B subunit binds to G M1 gangliosides, facilitating cell entry of the catalytic A subunit.
  • A subunit modifies Gs protein, attaching ADP-ribose to an arginine residue.
  • Modification stabilizes GTP-bound Gs, perpetually activating the signal-transduction pathway.
  • Continuous activation of protein kinase A (PKA) leads to chloride channel opening and Na+-H+ exchanger inhibition.
  • Result: Excessive loss of NaCl and water into the intestine.
  • Clinical Impact:

    • Cholera patients may lose as much as twice their body weight in fluid.
    • Treatment involves rehydration with a glucose-electrolyte solution.

Pertussis Toxin and G-Protein Inhibition

Pertussis (whooping cough) is caused by Bordetella pertussis, secreting pertussis toxin.

  • Mechanism of Action:

    • Pertussis toxin adds an ADP-ribose moiety to Gi protein.
    • Gi protein normally inhibits adenyl cyclase, closes Ca2+ channels, and opens K+ channels.
    • Modification lowers Gi protein's affinity for GTP, trapping it in the "off" conformation.
  • Clinical Impact:

    • Pulmonary symptoms in pertussis are not yet linked to a specific G protein target.

Overview:

  • Cholera and pertussis represent only two examples of G-protein-related diseases.
  • Given that G proteins relay signals for over 500 receptors, more diseases are likely to emerge.
    Defects in Signaling Pathway and Consequences | Zoology Optional Notes for UPSC

Src Protein Structure and Activation

Overview:

  • Src protein includes SH3, SH2, protein kinase domains, and a carboxyl-terminal tail with a key tyrosine residue.
  • Inactive Conformation:

    • Inactive c-Src has phosphorylated tyrosine bound in the SH2 domain; SH3 domain holds kinase domain inactive.
    • Activation pathways: (1) SH2 domain displacement, (2) dephosphorylation, (3) SH3 domain displacement.

Bcr-Abl Gene Translocation in Chronic Myelogenous Leukemia

Defects in Signaling Pathway and Consequences | Zoology Optional Notes for UPSC

  • Background:

    • Chromosomes 9 and 22 translocation causes the fusion of bcr and abl genes.
    • Protein kinase encoded by bcr-abl is overexpressed compared to c-abl in normal cells.
  • Clinical Implications:

    • Higher expression of Bcr-Abl in leukemia cells offers a unique target for chemotherapy.
    • Clinical trials with Bcr-Abl kinase inhibitors show promising results, with over 90% positive responses.

Diseases of Heterotrimeric G Proteins

  • Excessive Signaling:
    • Cholera:
      • Acute diarrheal disease caused by Vibrio cholera.
      • Choleragen toxin modifies Gs protein, leading to perpetual activation of the signal-transduction pathway.
      • Results in voluminous secretion of electrolytes and fluids in the intestines.
    • Cancer (Adenoma) of Pituitary and Thyroid:
      • Overactive G protein signaling associated with adenoma formation.
    • Essential Hypertension:
      • Abnormal G protein signaling implicated in hypertension.
  • Deficient Signaling:
    • Night Blindness:
      • Impaired G protein signaling affecting vision in low-light conditions.
    • Pseudohypoparathyroidism Type Ib:
      • G protein-related deficiency causing symptoms resembling hypoparathyroidism.
    • Pertussis:
      • Whooping cough caused by Bordetella pertussis, secreting pertussis toxin.
      • Toxin modifies Gi protein, inhibiting adenyl cyclase and impacting calcium and potassium channels.

Evolutionary Relationships in Signal-Transduction Pathways

1. Ancient Features:

  • cAMP Signaling:
    • Ancient signaling molecule for energy needs in prokaryotes and eukaryotes.
    • Different mechanisms for detecting cAMP in prokaryotes and eukaryotes.
  • GTP-Binding Proteins:
    • G subunits of heterotrimeric G proteins and Ras family members part of an ancient superfamily.
    • Superfamily includes proteins involved in ATP synthesis, molecular motion, and protein synthesis.
    • These proteins function as molecular "on-off" switches.

2. Early Evolution of Switch Domain:

  • Domain allowing conformational changes on binding and hydrolyzing nucleoside triphosphates.
  • Likely originated early in evolution and adapted for various biochemical functions.
  • Later Evolutionary Developments:
    • Eukaryotic Protein Kinases:
      • Among the largest protein families in eukaryotes, absent in prokaryotes.
      • Evolution of the protein kinase domain a significant step in the emergence of eukaryotes and multicellular organisms.
    • Conservation of Signaling Pathways:
      • Examples like the EGF signal-transduction pathway in Drosophila conserved in mammals.
      • Indicates pathway wiring at least 800 million years old.
        Defects in Signaling Pathway and Consequences | Zoology Optional Notes for UPSC

Conclusion

Understanding diseases associated with heterotrimeric G proteins provides crucial insights into both excessive and deficient signaling. Exploring the evolutionary relationships in signal-transduction pathways reveals ancient features that have been conserved across diverse organisms, highlighting the remarkable complexity and adaptability of these molecular systems over millions of years.

The document Defects in Signaling Pathway and Consequences | Zoology Optional Notes for UPSC is a part of the UPSC Course Zoology Optional Notes for UPSC.
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FAQs on Defects in Signaling Pathway and Consequences - Zoology Optional Notes for UPSC

1. What is the role of Cholera Toxin in G-Protein dysregulation?
Ans. Cholera Toxin is a bacterial toxin produced by Vibrio cholerae that causes cholera, a severe diarrheal disease. This toxin specifically targets and modifies G-proteins in the intestinal epithelial cells. It ADP-ribosylates the alpha subunit of the G-protein, leading to its constitutive activation and prolonged stimulation of adenylate cyclase. This results in increased levels of cyclic AMP (cAMP), causing the secretion of electrolytes and water into the intestinal lumen, leading to the characteristic watery diarrhea seen in cholera.
2. How does Pertussis Toxin inhibit G-Proteins?
Ans. Pertussis Toxin is a bacterial toxin produced by Bordetella pertussis, the causative agent of whooping cough. This toxin inhibits the function of G-proteins by ADP-ribosylating the alpha subunit of the G-protein. Specifically, it targets the alpha subunit of the inhibitory G-protein (Gi), preventing its interaction with adenylyl cyclase. As a result, the inhibitory signaling pathway mediated by Gi is disrupted, leading to increased cAMP levels and altered cellular responses.
3. What are G-Protein-Related Diseases?
Ans. G-Protein-Related Diseases refer to a group of disorders that arise due to dysregulation or malfunctioning of G-proteins and their associated signaling pathways. These diseases can result from mutations in genes encoding G-proteins, their receptors, or downstream signaling components. Examples of G-Protein-Related Diseases include pseudohypoparathyroidism, which is characterized by resistance to parathyroid hormone due to defects in G-protein signaling, and various cancers that involve aberrant activation of G-protein-coupled receptors (GPCRs).
4. How is the Src protein structured and activated?
Ans. The Src protein is a non-receptor tyrosine kinase that plays a crucial role in cell signaling. Structurally, it consists of several domains, including an N-terminal myristoylation site, a unique domain, a Src homology 3 (SH3) domain, a Src homology 2 (SH2) domain, a catalytic domain, and a C-terminal regulatory tail. The activation of Src involves phosphorylation events and conformational changes. When Src is in its inactive state, the C-terminal tail interacts with the catalytic domain, blocking its activity. Upon stimulation by external signals, phosphorylation of specific tyrosine residues in the C-terminal tail disrupts this inhibitory interaction, leading to Src activation.
5. What are the consequences of defects in signaling pathways?
Ans. Defects in signaling pathways can have various consequences depending on the specific pathway affected and the nature of the defect. Some common consequences include abnormal cellular responses, impaired development or tissue homeostasis, increased susceptibility to diseases, and altered physiological functions. For example, defects in the Wnt signaling pathway can lead to developmental abnormalities and cancer, while defects in the insulin signaling pathway can result in insulin resistance and diabetes. Understanding these consequences is crucial for diagnosing and treating signaling pathway-related disorders.
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