Deck 6: Microbial Genomics

A) Dozens
B) Hundreds
C) Thousands
D) Millions

A) Almost all archaeal genes are more similar to eukaryotic genes than to bacterial genes.
B) Almost all archaeal genes are more similar to bacterial genes than to eukaryotic genes.
C) Genes in Archaea involved in DNA replication, transcription, and translation are more similar to those of Eukarya, while those encoding metabolic functions other than information processing are more similar to those of Bacteria.
D) Archaeal genes are almost universally unique; very few are similar to either eukaryotic or bacterial genes.

A) miniaturization of reaction size.
B) increased computing power.
C) increased length of DNA sequences obtained.
D) miniaturization of reaction size and increased computer power.

A) Archaea.
B) hyperthermophiles.
C) rapidly evolving species.
D) pathogens.

A) metagenomics.
B) proteomics.
C) bioinformatics.
D) genomics.

A) analyze global gene expression.
B) detect pathogens.
C) detect unwanted food additives or substitutes.
D) detect pathogens, analyze global gene expression, and detect unwanted food additives or substitutes.

A) percentage of GC content and codon usage
B) genome size and number of introns
C) number of genes in the pan genome
D) ribosomal binding site and intron sequence

A) it is NOT dependent on nucleic acid sequencing technology.
B) it results in amino acid sequence and is, thus, easier to analyze.
C) it analyzes RNA, thus it reveals which genes are expressed under different conditions.
D) it reveals interactions between molecules and, thus, provides more information than genome analysis.

A) array.
B) genome.
C) proteome.
D) transcriptome.

A) plant.
B) autotrophic bacterium.
C) chloroplast.
D) autotrophic archaeon.

A) variable numbers of protein-encoding genes
B) large stretches of AT-rich DNA
C) linear and circular genome structure in different organisms
D) rRNA genes most closely related to Bacteria

A) nanopore technology that separates DNA molecules based on charge differences.
B) the incorporation of dideoxynucleotides that terminate chain extension during DNA synthesis.
C) nuclear magnetic resonance (NMR) analysis.
D) the release of protons whenever a new nucleotide is added to a growing strand of DNA.

A) a carbohydrate.
B) a polypeptide.
C) mRNA.
D) a carbohydrate or a polypeptide.

A) 10
B) 100
C) 1,000
D) 10,000

A) DNA repair and replication.
B) virulence, biodegradation of pollutants, and symbiotic relationships.
C) catabolic and anabolic reactions.
D) antibiotic resistance.

A) Homo sapiens > Arabidopsis thaliana > Plasmodium falciparum > Cryptosporidium parvum
B) Cryptosporidium parvum > Plasmodium falciparum > Arabidopsis thaliana > Homo sapiens
C) Homo sapiens > Cryptosporidium parvum > Plasmodium falciparum > Arabidopsis thaliana
D) Intron frequency cannot be used to predict genome size in eukaryotes.

A) transcription.
B) energy and coenzyme production.
C) cell membrane functions.
D) carbohydrate metabolism.

A) transposable elements.
B) introns.
C) linear chromosomes.
D) plasmids.

A) common to all strains of the same species.
B) present in one or more strains of the same species.
C) shared with all other prokaryotes.
D) hypothetical or uncharacterized genome content of a species.

A) chromosomal island.
B) interactome.
C) metagenome.
D) metabolome.

A) virus.
B) bacterium.
C) eukaryote.
D) archaeon.

A) bacteria / chromosome reduction
B) plants / gene deletion
C) bacteria / endosymbiosis
D) plants / endosymbiosis

A) metabolome.
B) transcriptome.
C) interactome.
D) metagenome.

A) autotrophy / DNA replication
B) photosynthesis / glycolysis
C) autotrophy / glycolysis
D) photosynthesis / oxidative phosphorylation

A) metabolomics
B) metagenomics
C) transcriptomics
D) proteomics

A) Too many ORFS are identified, most of which are stretches on non-coding junk DNA.
B) Codon bias causes incorrect annotations.
C) Unusual, but legitimate genes and non-coding RNA may be missed.
D) We lack the computing power to complete the analyses in a timely manner, thus many genomes are only partially annotated.

A) < 1 %
B) 5 %
C) 30 %
D) 90 %

A) DNA replication and repair.
B) virulence and metabolic functions.
C) only very few processes.
D) translation.

A) accurate gene annotation.
B) overlap of a large numbers of short sequences.
C) codon bias.
D) systems biology.

A) mass
B) pH
C) charge
D) light

A) homologous / gene families
B) paralogous / functional genes
C) orthologous / gene families
D) homologous / functional genes

A) unique compared to all other prokaryotes.
B) expressed under all environmental conditions.
C) shared between all other prokaryotes.
D) shared between all strains of a species.

A) parasite
B) endosymbiont
C) autotroph
D) free-living heterotroph

A) ion torrent semiconductor sequencing
B) mass spectrometry
C) 2D polyacrylamide gel electrophoresis
D) Sanger method

A) is rare and only occurs between closely related strains.
B) is common and may sometime occur between unrelated organisms.
C) does not provide an advantage to organisms.
D) only occurs in prokaryotes.

A) metagenome.
B) metabolome.
C) interactome.
D) transcriptome.

A) annotation.
B) assembly.
C) codon bias.
D) expression.

A) plasmids.
B) transposons.
C) proteomes.
D) lysosomes.

A) noncoding RNA.
B) codon bias.
C) number of ORFs.
D) number of introns.

A) from microbes grown in the lab.
B) viral in origin.
C) eukaryotic in origin.
D) from extinct microorganisms.