Explanation: This statement is incorrect. Endosymbionts, by definition, live *within* the body or cells of another organism. Organisms living exclusively outside are typically considered ectosymbionts or free-living.

Explanation: This assertion is inaccurate. While parasitic relationships exist, the majority of endosymbiotic associations are mutualistic, where both the host and the symbiont derive benefits.

Explanation: This statement is incorrect. An obligate endosymbiont is defined by its absolute dependence on the host organism for survival. Facultative endosymbionts are those capable of independent existence.

Explanation: The term 'endosymbiont' originates from Greek roots: 'endon' (within), 'syn' (together), and 'biosis' (living). Latin roots are not the primary source for this term.

Explanation: This definition is incomplete. A holobiont encompasses the host organism *and* all of its associated microbial symbionts, functioning as an integrated unit.

Explanation: An endosymbiont is an organism that lives within the body or cells of another organism, forming a symbiotic association.

Explanation: The mutualistic association between corals and their endosymbiotic dinoflagellates (zooxanthellae) is a classic and widespread example of endosymbiosis, crucial for coral reef ecosystems.

Explanation: A facultative endosymbiont is defined by its ability to exist independently outside of a host organism, although it may also live symbiotically within a host.

Explanation: The term 'holobiont' refers to the host organism and all of its associated microbial symbionts, viewed as a single ecological and evolutionary unit.

Explanation: This is contrary to observed patterns. As endosymbionts become more integrated, their genomes typically undergo reduction, losing genes that are redundant or provided by the host, rather than expanding.

Explanation: This statement is incorrect. Horizontal symbiont transfer involves the acquisition of symbionts from the external environment or other hosts, distinct from vertical transmission, which is parent-to-offspring inheritance.

Explanation: This statement is incorrect. Vertical transmission ensures symbionts are passed directly to offspring, often reducing the need for independent survival and potentially leading to genome reduction, rather than requiring it.

Explanation: Cospeciation is more commonly associated with primary endosymbionts, which typically have long-term co-evolutionary relationships with their hosts, rather than secondary endosymbionts that are often acquired more recently and are not obligate.

Explanation: This statement accurately describes the evolutionary pressures leading to genome reduction in obligate endosymbionts: the availability of host-provided resources and functions, coupled with the reduced selective pressure for maintaining genes related to independent survival.

Explanation: Obligate endosymbionts often experience genome reduction. This process involves the loss of genes that are no longer essential for survival because the host provides the corresponding functions or molecules, leading to a streamlined genome.

Explanation: Horizontal transmission refers to the acquisition of symbionts from sources external to the host's lineage, such as the environment or other individuals, as opposed to direct inheritance from parents.

Explanation: Vertical transmission ensures a consistent supply of symbionts to offspring. This can reduce the selective pressure for independent survival, potentially leading to the loss of genes required for free-living existence and subsequent genome reduction.

Explanation: Cospeciation describes the simultaneous evolutionary divergence of host and symbiont lineages, indicating a long-standing and tightly co-evolved relationship.

Explanation: The stable intracellular environment and the host's provision of essential metabolites reduce the selective pressure for maintaining genes related to independent survival, leading to genome streamlining.

Explanation: Endosymbionts can introduce new metabolic pathways (e.g., nutrient synthesis) or alter host physiology, providing adaptive advantages that drive host evolution, potentially leading to niche expansion or diversification.

Explanation: Obligate symbionts are intrinsically dependent on their host and usually rely on vertical transmission for propagation. Facultative symbionts, capable of independent survival, are often acquired horizontally from the environment.

Explanation: The prevailing endosymbiotic theory posits that chloroplasts originated from the engulfment of cyanobacteria, not archaea, approximately 1 to 1.5 billion years ago.

Explanation: This statement accurately reflects the core tenet of the symbiogenesis theory, which proposes that organelles like mitochondria and chloroplasts originated from free-living prokaryotes that were engulfed by host cells and established enduring endosymbiotic relationships.

Explanation: The endosymbiotic theory posits that mitochondria originated from an aerobic bacterium that was engulfed by an early eukaryotic precursor cell.

Explanation: Symbiogenesis is the leading theory explaining the origin of eukaryotic cells, proposing that complex cellular structures and organelles arose from symbiotic relationships between different prokaryotic organisms.

Explanation: This statement is accurate. Primary endosymbionts (P-endosymbionts) often exhibit long-term co-evolutionary histories with their insect hosts, sometimes spanning millions of years, which can lead to phenomena like cospeciation.

Explanation: This statement is incorrect. *Buchnera* primarily synthesizes essential amino acids that are deficient in the aphid's plant sap diet, not essential vitamins.

Explanation: This statement is correct. *Hamiltonella defensa* is known to provide a defensive benefit to pea aphids by producing toxins that incapacitate or kill parasitoid wasps attempting to lay eggs in the aphid.

Explanation: *Wigglesworthia* is an obligate primary endosymbiont of the tsetse fly, essential for providing vital vitamins that the fly cannot obtain from its blood-based diet.

Explanation: Secondary endosymbionts are typically acquired horizontally from the environment and are not obligate for host survival, distinguishing them from primary endosymbionts which are often vertically transmitted and essential.

Explanation: *Spiroplasma poulsonii* has been shown to confer protection to *Drosophila* flies against nematode infections by producing toxins that target the parasites.

Explanation: *Wigglesworthia* is an obligate endosymbiont crucial for synthesizing essential vitamins that the tsetse fly cannot obtain from its blood diet.

Explanation: Understanding the dependencies of insect pests or disease vectors on their essential endosymbionts can inform the development of targeted control strategies, such as disrupting symbiont transmission or function.

Explanation: This statement is correct. The symbiotic relationship between Rhizobia bacteria and legumes, where the bacteria reside within root nodules and fix atmospheric nitrogen, is a well-established example of endosymbiosis.

Explanation: This statement accurately reflects the multifaceted benefits endophytes can confer upon their vascular plant hosts, encompassing physiological support and protective functions.

Explanation: This assertion is incorrect. While many plant endosymbionts are mutualistic or commensal, some can be pathogenic or exhibit conditional benefits, meaning their impact can vary depending on environmental factors or host status.

Explanation: AMF primarily help plants by providing them with soil nutrients, like phosphorus and nitrogen, in exchange for carbohydrates produced by the plant through photosynthesis.

Explanation: Plants attract AMF by releasing chemical signals, such as strigolactones and flavonoids, from their roots, not their leaves.

Explanation: Endophytic fungi colonize the internal tissues of plants, residing within host cells or intercellular spaces, rather than solely on the exterior.

Explanation: True endophytes possess specific adaptive traits that enable consistent association with host plants, unlike 'passenger' endophytes which colonize randomly.

Explanation: Legume hosts release flavonoids from their roots, which act as chemoattractants and signal molecules that induce the expression of *Nod* genes in Rhizobia, thereby initiating the nodulation process.

Explanation: Endophytes can significantly benefit their host plants by promoting growth, enhancing the uptake of essential nutrients, and bolstering resistance to environmental stresses and herbivory.

Explanation: AMF colonize plant roots and enhance nutrient uptake, primarily receiving photosynthetically derived carbohydrates (sugars) from the plant in exchange.

Explanation: Chemical signals, such as strigolactones and flavonoids, are released from plant roots to attract AMF, initiating the symbiotic colonization process.

Explanation: True endophytes have evolved mechanisms for stable integration and often provide benefits, whereas passenger endophytes colonize plant tissues incidentally without specialized adaptations for long-term association.

Explanation: This statement contains two inaccuracies: Zooxanthellae are dinoflagellate algae, not bacteria, and they provide energy to corals via photosynthesis, not chemosynthesis.

Explanation: This statement is incorrect. While photosynthesis is vital, the primary significance of *Richelia intracellularis* in nutrient-poor oceans lies in its capacity for nitrogen fixation, providing essential nitrogen to its diatom host.

Explanation: This statement is incorrect. The bacteria hosted by *Mixotricha paradoxa* are primarily involved in respiration and methanogenesis, not photosynthesis.

Explanation: This statement is incorrect. The chromatophore, derived from a cyanobacterial endosymbiont, is functionally analogous to chloroplasts, responsible for photosynthesis, not mitochondria which are involved in cellular respiration.

Explanation: This statement is incorrect. The study indicated that initial infections could be lethal, but prolonged co-evolutionary processes eventually resulted in a stable, mutually dependent relationship.

Explanation: This finding is significant as it demonstrates the experimental induction of endosymbiosis and suggests that such interactions can lead to changes in the host's DNA, offering new avenues for studying the dynamics of symbiosis.

Explanation: Zooxanthellae are widely known for their mutualistic symbiosis with reef-building corals and various bivalves, such as giant clams, providing them with photosynthetic products.

Explanation: Zooxanthellae are photosynthetic algae; they convert light energy into chemical energy in the form of organic compounds, which are then shared with their coral hosts.

Explanation: The cyanobacterial endosymbiont within *Paulinella chromatophora* has undergone significant evolutionary changes, developing into a specialized organelle termed a chromatophore, which performs photosynthesis, representing a distinct event of organelle evolution.

Explanation: These protists possess the enzymatic machinery necessary to break down cellulose and lignin, complex carbohydrates found in wood and plant matter, thereby allowing termites to utilize these materials as a food source.

Explanation: The cyanobacterium *Richelia* possesses the metabolic capability to fix atmospheric nitrogen, a crucial nutrient often scarce in oceanic waters. This nitrogen fixation directly benefits its diatom host, *Hemialus*, supporting its growth and productivity.

Explanation: This research achieved the experimental induction of endosymbiosis, providing a model system to investigate the molecular mechanisms underlying symbiotic establishment and potential genetic exchanges between host and symbiont.