Q&A Hero

Q: The Human Microbiome Project is a large research program that aims to understand all of the microorganisms on and in the human body. Which "-omic" methods could be applied directly to a sample from the human body to study the microorganisms in the sample? Propose a general experimental approach for analyzing a sample containing a complex mixture of microorganisms.

Q: Explain how mass spectrometry (MS) has aided in the progression of the field of metabolomics.

Q: How does the FoodExpert-ID identify macroorganisms and why is this significant?

Q: What process allows evolution to "experiment" with genes to create novel functions? How is this manifested in extant genes (presently existing) and their relationships to each other?

Q: When analyzing the sequence of genes similar to ones already known, why is the amino acid sequence of the protein more important than the DNA sequence?

Q: Explain why the proteome is NOT defined as "all the proteins encoded by an organism's genome."

Q: Explain why larger genomes contain more genes devoted to regulation than smaller genomes and why these genes increase the competitiveness of organisms.

Q: The intracellular parasite Nanoarchaeum equitans has one of the smallest prokaryotic genomes. Why is the genome of N. equitans so small? How is it possible that the genome of N. equitans contains more genes than that of Mycoplasma genitalium, which is actually 90 kbp larger?

Q: Explain why organisms undergoing rapid evolutionary change often contain relatively large numbers of mobile DNA elements, whereas once organisms settle into a stable evolutionary niche, most of these mobile elements are lost.

Q: Chromosomal islands are presumed to have a "foreign" origin based upon three observations. What are these observations and how do they indicate that chromosomal islands are "foreign" in origin?

Q: Recommend what type of data should be collected and analyzed in a systems biology approach to investigate how a non-pathogenic bacterial strain becomes pathogenic. Describe what scientific fields and methods would be involved in your recommendation.

Q: Design an experiment using omic methods to test how Escherichia coli adapts to different growth temperatures.

Q: Interpret the genomic content of mitochondria in relation to their evolution. How is mitochondrial evolution more complicated than expected?

Q: Explain the terms "core genome" and "pan genome" and describe how each contributes to the genome of a bacterial species. Give an example of genes that are part of a core genome versus those that are more often in the pan genome.

Q: Why are the words "about" and "approximately" used in discussing the results of genomic analysis? Predict what advances in knowledge or methods could change our understanding of a genome sequence.

Q: Explain horizontal gene transfer and demonstrate how this phenomenon has complicated evolutionary studies using a diagram that illustrates phylogenetic relationships between organisms and genes.

Q: Explain how codon bias and GC content can be used to detect horizontal gene transfer within a genome.

Q: You are interested in the minimum set of genes necessary for survival of a eukaryotic microorganism such as Saccharomyces cerevisiae. Design an experiment to systematically test which genes are essential for survival and which are not under high nutrient, aerobic conditions.

Q: After transcription, mRNA may undergo significant editing. Compare and contrast RNA editing in prokaryotes and eukaryotes and connect how these differences affect genome size and gene content.

Q: With modern molecular techniques, it is now possible to completely assemble a genome from a single cell.

Q: Microorganisms that grow in extreme environments typically contain larger genomes when compared to microbes that grow in non-extreme environments.

Q: Some virulence genes are carried on plasmids or lysogenic bacteriophages.

Q: Chromosomal rearrangements due to insertion sequences have apparently contributed to the evolution of several human pathogens.

Q: Horizontally transferred genes typically encode essential metabolic functions such as DNA replication, transcription, and translation.

Q: Few genes in all organisms have common evolutionary roots.

Q: The relative percentage of genes devoted to protein synthesis in small-genome organisms is high compared with that of large-genome organisms.

Q: Genes for DNA replication and transcription make up only a small fraction of the typical prokaryotic genome.

Q: Codon usage and even the genetic code itself varies from one organism to the next.

Q: The largest cellular genomes belong to prokaryotes that are parasitic or pathogenic.

Q: Heterotrophs need only a few more genes than autotrophs.

Q: The key characteristic of third-generation sequencing is the ability to sequence single molecules of DNA.

Q: Paralogs always have the same function.

Q: Despite having smaller genomes, the protozoans Paramecium and Trichomonas have significantly more genes than humans.

Q: Based on the evolutionary tree shown below, RubisCO Form II and RLP beta are orthologs.

Q: Gene families are composed of homologous genes that have different evolutionary origins but the same function.

Q: It is generally accepted that independent mutation rather than gene duplication is the mechanism for evolution of most new genes.

Q: Reconstructing evolutionary relationships helps in differentiating between primitive and derived characteristics.

Q: Comparative genomics helps us to understand evolutionary relationships between organisms.

Q: Genomic analysis led to the discovery that pathogenic organisms often lack genes for amino acid biosynthesis.

Q: Knowledge of an organism's genome sequence yields important clues to how an organism functions and its evolutionary history.

Q: A surprising finding of environmental metagenomic studies is that a majority of genes in the environment are A) from microbes grown in the lab. B) viral in origin. C) eukaryotic in origin. D) from extinct microorganisms.

Q: Horizontal gene transfer has been thoroughly documented for genes involved in A) DNA replication and repair. B) virulence and metabolic functions. C) only very few processes. D) translation.

Q: Horizontal gene transfer 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.

Q: Genes from different sources that are related in sequence due to shared evolutionary ancestry are called ________ genes, and groups of such genes are known as ________. A) homologous / gene families B) paralogous / functional genes C) orthologous / gene families D) homologous / functional genes

Q: RNA-Seq analysis is a method aimed at defining a(n) A) metabolome. B) transcriptome. C) interactome. D) metagenome.

Q: Fourth-generation sequencing methods no longer use ________ to detect nucleotide incorporation. A) mass B) pH C) charge D) light

Q: Typically ________ of ORFs in a genome cannot clearly be assigned a function. These ORFs are usually assigned and predicted to encode hypothetical proteins. A) < 1 % B) 5 % C) 30 % D) 90 %

Q: Genomes of species in both Bacteria and Archaea show a strong correlation between genome size and A) noncoding RNA. B) codon bias. C) number of ORFs. D) number of introns.

Q: Compounds such as pyruvate, acetyl-CoA, fructose-6-phosphate, oxaloacetate, and other small organic compounds could be part of a(n) A) metagenome. B) metabolome. C) interactome. D) transcriptome.

Q: The core genome of a prokaryotic species is the genomic content that is 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.

Q: Genome assembly relies on A) accurate gene annotation. B) overlap of a large numbers of short sequences. C) codon bias. D) systems biology.

Q: Many of the genes in the chloroplast genome encode proteins involved in ________, whereas mitochondrial genomes primarily encode proteins involved in ________. A) autotrophy / DNA replication B) photosynthesis / glycolysis C) autotrophy / glycolysis D) photosynthesis / oxidative phosphorylation

Q: Which method is most commonly used in metabolomics? A) ion torrent semiconductor sequencing B) mass spectrometry C) 2D polyacrylamide gel electrophoresis D) Sanger method

Q: Gene function is annotated based on homology between the ORFs of a genome and proteins whose function has been proven experimentally. What "-omic" approach could help us determine the function and structure of proteins encoded by uncharacterized ORFs? A) metabolomics B) metagenomics C) transcriptomics D) proteomics

Q: In addition to chromosomes, some mitochondria also contain other genetic material known as A) plasmids. B) transposons. C) proteomes. D) lysosomes.

Q: Chloroplasts and mitochondria originated from ________ by a process known as ________. A) bacteria / chromosome reduction B) plants / gene deletion C) bacteria / endosymbiosis D) plants / endosymbiosis

Q: In general, prokaryotic genome size is correlated to lifestyle. Which type of prokaryote typically has the smallest genome? A) parasite B) endosymbiont C) autotroph D) free-living heterotroph

Q: The first genome sequenced was that of a A) virus. B) bacterium. C) eukaryote. D) archaeon.

Q: Linking an ORF with a specific function is an example of gene A) annotation. B) assembly. C) codon bias. D) expression.

Q: The total genetic complement of ALL cells within a microbial community is called a(n) A) chromosomal island. B) interactome. C) metagenome. D) metabolome.

Q: A computer program recognizes an ORF by looking for ribosomal binding sites, start codons, and stop codons with an appropriate number of nucleotides between each element. What is a drawback of this approach? 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.

Q: Chromosomal islands contain clusters of genes for A) DNA repair and replication. B) virulence, biodegradation of pollutants, and symbiotic relationships. C) catabolic and anabolic reactions. D) antibiotic resistance.

Q: Mobile DNA elements are more common in the genomes of A) Archaea. B) hyperthermophiles. C) rapidly evolving species. D) pathogens.

Q: Most mobile DNA consists of A) transposable elements. B) introns. C) linear chromosomes. D) plasmids.

Q: The science that applies powerful computational tools to DNA and protein sequences for the purpose of analyzing, storing, and accessing the sequences for comparative purposes is known as A) metagenomics. B) proteomics. C) bioinformatics. D) genomics.

Q: You want to know whether the virulence genes present in Bordetella pertussis are evolutionarily related to genes in the less pathogenic species B. bronchiseptica or if the virulence genes were acquired via horizontal gene transfer. What characteristic(s) would you compare to answer this question? 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

Q: Within Archaea and Bacteria, one megabasepairs of DNA encode about ________ open reading frames. A) 10 B) 100 C) 1,000 D) 10,000

Q: The advantage(s) of second-generation DNA sequencing compared to the Sanger method are the result of 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.

Q: The very first DNA sequencing technology called the Sanger method relies on 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.

Q: The entire complement of RNA produced under a given set of conditions is called a(n) A) array. B) genome. C) proteome. D) transcriptome.

Q: When compared with Bacteria, species of Archaea seem to devote a higher percentage of their genomes to genes encoding proteins involved in A) transcription. B) energy and coenzyme production. C) cell membrane functions. D) carbohydrate metabolism.

Q: The most abundant genes in prokaryotic genomes are A) those involved in metabolism. B) those involved in translation. C) those involved in transport. D) those involved in DNA replication.

Q: Transcriptome analysis is useful in relation to genome analysis because 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.

Q: Microarrays can be used to 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.

Q: The pan genome of a species is the genomic content that is 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.

Q: An open reading frame (ORF) encodes for A) a carbohydrate. B) a polypeptide. C) mRNA. D) a carbohydrate or a polypeptide.

Q: The evolutionary origin of mitochondria is demonstrated by which of the following key genomic characteristics? 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

Q: The 140 kbp genome containing many short repeats, ribosomal RNA genes, one RNA polymerase gene (rpo) and one RubisCO gene (rbcL) is most likely from a(n) A) plant. B) autotrophic bacterium. C) chloroplast. D) autotrophic archaeon.

Q: Based on the table of average intron frequency given below, predict the relative order of genome size for these four eukaryotic organisms. Organism Average Intron Frequency Cryptosporidium parvum 0 Plasmodium falciparum 1 Arabidopsis thaliana 5 Homo sapiens 8 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.

Q: When comparing genes from Archaea, Bacteria, and Eukarya, which statement is TRUE? 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.