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Genomics — MCQs Biology

1. Genomics is the study of:

(A) Proteins only


(B) Metabolic pathways


(C) The complete set of DNA in an organism


(D) Cellular organelles




2. The human genome consists of approximately:

(A) 23 genes


(B) 3 million base pairs


(C) 46 chromosomes


(D) 3 billion base pairs




3. The first complete human genome sequence was published in:

(A) 1985


(B) 1990


(C) 2010


(D) 2003




4. Functional genomics aims to study:

(A) Chromosome structure


(B) Protein degradation


(C) DNA replication


(D) Gene expression and function




5. Structural genomics focuses on:

(A) DNA sequence and arrangement


(B) Gene expression


(C) Protein function


(D) RNA splicing




6. Comparative genomics compares:

(A) Protein sequences in one species


(B) DNA sequences between species


(C) RNA sequences only


(D) Metabolic pathways




7. The reference genome provides:

(A) Complete protein sequences


(B) Chromosome shapes


(C) RNA transcripts


(D) A representative DNA sequence for a species




8. Which technique is commonly used for whole-genome sequencing?

(A) Sanger sequencing


(B) PCR


(C) Northern blot


(D) Microarray




9. Next-generation sequencing (NGS) allows:

(A) High-throughput sequencing of entire genomes


(B) Sequencing of a few genes


(C) Protein sequencing only


(D) RNA splicing




10. Transcriptomics studies:

(A) DNA


(B) Metabolites


(C) Proteins


(D) RNA expression




11. Proteomics focuses on:

(A) RNA molecules


(B) Chromosome number


(C) DNA methylation


(D) Entire set of proteins in a cell




12. Epigenomics studies:

(A) DNA sequence only


(B) Chemical modifications affecting gene expression


(C) RNA sequence


(D) Protein folding




13. Epigenetic changes include:

(A) DNA methylation and histone modification


(B) Point mutations


(C) Chromosome duplication


(D) Frameshift mutations




14. SNPs are:

(A) Single nucleotide polymorphisms


(B) Structural chromosome mutations


(C) Protein domains


(D) RNA variants




15. Comparative genomics helps in:

(A) Understanding evolutionary relationships


(B) Identifying proteins


(C) RNA sequencing


(D) Cell division




16. Metagenomics studies:

(A) DNA from environmental microbial communities


(B) Genes of a single organism


(C) Chromosome structure


(D) Protein synthesis




17. Functional annotation of a genome identifies:

(A) Chromosome number


(B) Protein folding


(C) Genes and their biological roles


(D) RNA splicing




18. Exome sequencing targets:

(A) Only protein-coding regions


(B) Entire genome


(C) Non-coding DNA


(D) Mitochondrial DNA




19. The human exome represents approximately:

(A) 10% of the genome


(B) 1-2% of the genome


(C) 50% of the genome


(D) 100% of the genome




20. Structural variations include:

(A) Insertions, deletions, duplications, inversions


(B) SNPs only


(C) RNA modifications


(D) Protein phosphorylation




21. The HapMap project studies:

(A) Protein sequences


(B) SNP patterns in human populations


(C) RNA transcription


(D) Chromosome number




22. Genome-wide association studies (GWAS) identify:

(A) RNA folding


(B) Chromosome shapes


(C) SNPs linked to diseases


(D) Protein domains




23. The 1000 Genomes Project aimed to:

(A) Sequence 1000 human proteins


(B) Catalog genetic variation in human populations


(C) Sequence microbial genomes


(D) Map metabolic pathways




24. Mitochondrial genomics studies:

(A) Nuclear DNA only


(B) RNA expression


(C) Mitochondrial DNA sequences


(D) Protein folding




25. Chloroplast genomics studies:

(A) Chloroplast DNA


(B) Nuclear genes


(C) Mitochondrial DNA


(D) RNA only




26. Comparative genomics of humans and chimpanzees shows:

98% DNA similarity')"> (A) 10% DNA similarity


98% DNA similarity')"> (B) 70% DNA similarity


98% DNA similarity')"> (C) 50% DNA similarity


98% DNA similarity')"> (D) >98% DNA similarity




27. Pan-genome represents:

(A) Genes shared among all strains of a species


(B) Genes unique to one species


(C) Only essential genes


(D) Protein domains




28. Orthologous genes are:

(A) Genes duplicated within a genome


(B) Mutated genes only


(C) Genes with no function


(D) Genes in different species with common ancestry




29. Paralogs are:

(A) Genes in different species


(B) Transposable elements


(C) Non-coding DNA


(D) Duplicate genes within a genome




30. Bioinformatics in genomics is used for:

(A) Protein synthesis


(B) Analyzing and interpreting genome data


(C) RNA transcription


(D) Chromosome segregation




31. Genome assembly refers to:

(A) Sequencing RNA


(B) Piecing together DNA fragments to reconstruct the genome


(C) Protein folding


(D) Chromosome staining




32. Transcriptome sequencing (RNA-Seq) provides information on:

(A) DNA sequence only


(B) Chromosome number


(C) Protein folding


(D) RNA expression levels




33. Epigenetic markers can be inherited:

(A) Only in mitochondria


(B) No


(C) Only in bacteria


(D) Yes, across generations




34. Functional genomics uses technologies like:

(A) Microarrays


(B) PCR


(C) Gel electrophoresis


(D) Western blot only




35. CRISPR-Cas9 in genomics is used for:

(A) RNA splicing


(B) Genome editing


(C) DNA replication


(D) Protein degradation




36. Genome annotation involves:

(A) Sequencing RNA


(B) Chromosome replication


(C) Protein synthesis


(D) Assigning function to genes




37. Structural genomics can reveal:

(A) Metabolic pathways


(B) Protein folding patterns


(C) RNA expression


(D) Chromosome number




38. Microbiome genomics studies:

(A) Microbial genomes in an environment


(B) Human nuclear genome


(C) Protein sequences only


(D) Chromosomes




39. High-throughput sequencing is also called:

(A) Sanger sequencing


(B) Next-generation sequencing


(C) PCR


(D) Microarray




40. Comparative genomics helps in:

(A) Understanding gene function and evolution


(B) Studying protein folding only


(C) Measuring enzyme activity


(D) Chromosome segregation




41. Genomic imprinting involves:

(A) Gene duplication


(B) Parent-specific gene expression


(C) Random mutation


(D) RNA splicing




42. Copy number variations (CNVs) are:

(A) Large DNA segments that vary in number


(B) Single base changes


(C) Chromosome inversions


(D) RNA modifications




43. Genome sequencing has applications in:

(A) Medicine and diagnostics


(B) Agriculture


(C) Evolutionary biology


(D) All of the above




44. Synthetic genomics involves:

(A) Sequencing RNA only


(B) Creating artificial genomes


(C) Studying chromosomes only


(D) Measuring protein activity




45. Single-cell genomics studies:

(A) DNA from many cells


(B) Chromosome number


(C) Protein folding only


(D) DNA/RNA from individual cells




46. The ENCODE project aimed to:

(A) Map human protein sequences


(B) Study chromosome condensation


(C) Study microbial genomes


(D) Identify all functional elements in the human genome




47. Genomic islands are:

(A) Regions of RNA only


(B) DNA segments acquired via horizontal gene transfer


(C) Chromosome ends


(D) Protein-coding regions only




48. Telomere sequencing is part of:

(A) Mitochondrial genomics


(B) Epigenomics


(C) Nuclear genomics


(D) Proteomics




49. Pan-genome includes:

(A) Both A and B


(B) Accessory genes unique to some strains


(C) Core genes shared by all strains


(D) Only RNA sequences




50. Genomics has enabled personalized medicine by:

(A) Sequencing proteins only


(B) Identifying chromosome number


(C) Studying ribosomes only


(D) Predicting drug response based on genome




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