Explanation: Avian malaria is caused by parasites belonging to the genera *Plasmodium* and *Hemoproteus*, rendering the statement that it is exclusively caused by *Plasmodium* inaccurate.

Explanation: As stated in the supporting materials, the parasites responsible for avian malaria are classified as protozoa within the phylum Apicomplexa.

Explanation: *Plasmodium relictum* is indeed a significant cause of avian malaria and is distributed globally, notably absent only from the continent of Antarctica.

Explanation: While primarily affecting wild birds, species such as *Plasmodium anasum* and *Plasmodium gallinaceum* can also pose a threat to the poultry industry, contrary to the assertion that their impact is rare.

Explanation: Avian malaria parasites undergo both asexual and sexual reproduction within their insect vectors, meaning they do not reproduce solely asexually in this stage.

Explanation: *Plasmodium relictum* is the most common avian malaria species, and its epidemiology and geographical distribution are frequently studied using genetic variation in the nuclear gene MSP1 (merozoite surface protein 1).

Explanation: Sporozoites are immature forms of the malaria parasite that initiate the infection cycle. They are not the mature stage found within red blood cells.

Explanation: Upon entering a bird, sporozoites mature into merozoites within fibroblasts and macrophages. These merozoites are released into the bloodstream and subsequently infect macrophages in various organs, including the brain, liver, spleen, kidney, and lungs.

Explanation: The bursting of infected red blood cells releases merozoites, which leads to the acute phase of avian malaria, not the chronic phase.

Explanation: *Plasmodium relictum* causes anemia by reproducing within and destroying red blood cells, not by infecting bone marrow cells responsible for their production.

Explanation: Avian malaria parasites reproduce asexually within their avian hosts and undergo both asexual and sexual reproduction within their insect vectors, such as mosquitoes, biting midges, and louse flies.

Explanation: The primary genera responsible for causing avian malaria are *Plasmodium* and *Hemoproteus*, as detailed in the supporting materials.

Explanation: *Plasmodium relictum* is recognized as a significant cause of avian malaria and is found globally, with the notable exception of Antarctica.

Explanation: *Plasmodium relictum* is the most common avian malaria species, and its epidemiology and geographical distribution are frequently studied using genetic variation in the nuclear gene MSP1 (merozoite surface protein 1).

Explanation: During the acute phase of avian malaria infection in susceptible birds, the primary manifestations include anemia, resulting from the destruction of red blood cells, and general symptoms of illness.

Explanation: *Plasmodium relictum* causes anemia by reproducing within and destroying red blood cells, leading to a subsequent deficiency in oxygen-carrying capacity.

Explanation: While mosquitoes transmit *Plasmodium* species, biting midges are also vectors for avian malaria parasites, specifically *Hemoproteus*. Thus, mosquitoes are not the sole vectors for all types.

Explanation: Avian malaria is globally distributed, with notable exceptions such as Antarctica. Its introduction into naive populations, as seen in Hawaii, can result in devastating effects.

Explanation: Louse flies are known vectors for *Haemoproteus* species, not exclusively for *Plasmodium* species causing avian malaria. Mosquitoes are the primary vectors for *Plasmodium*.

Explanation: Migratory birds facilitate the dispersal of avian malaria parasites, influencing prevalence patterns across regions and altering host-parasite adaptation processes.

Explanation: Compared to parasite-avian interactions, the relationships between avian malaria parasites and their specific vectors are less explored. While databases like MalAvi document known vectors, comprehensive knowledge remains incomplete.

Explanation: The global incidence of avian malaria has not remained stable; it has nearly tripled over the past 70 years, often correlated with rising global temperatures that expand vector mosquito ranges and activity.

Explanation: Significant increases in malaria infection rates have been observed in European bird species, including house sparrows (rising from <10% to ~30%), great tits (3% to 15% since 1995), Eurasian blackcaps (~4% by 1999), and tawny owls (2-3% to 60% in the UK).

Explanation: Insect vectors for avian malaria parasites include mosquitoes (Culicidae) for *Plasmodium*, biting midges (Ceratopogonidae) for *Hemoproteus* and some *Plasmodium*, and louse flies (Hippoboscidae) for *Haemoproteus*.

Explanation: Mosquitoes, biting midges, and louse flies are identified as vectors for avian malaria parasites. Sandflies (family Psychodidae) are not listed among these vectors in the provided information.

Explanation: Migratory birds contribute to the spread of avian malaria by facilitating the dispersal of parasites across diverse geographical regions, thereby influencing prevalence patterns and host-parasite adaptation.

Explanation: The impact of avian malaria on bird populations can range from asymptomatic infections to severe population declines, as demonstrably observed in species such as the Hawaiian honeycreepers, according to relevant literature.

Explanation: Captive penguins in non-native environments exhibit high susceptibility to *Plasmodium relictum* due to a lack of co-evolutionary resistance with the parasite, often resulting in severe disease and mortality.

Explanation: While nesting height and sexual dimorphism are investigated factors influencing susceptibility to avian malaria, they are not definitively linked as the sole determinants. The overall effects in wild populations remain poorly understood.

Explanation: A 2015 study of Malawian bird fauna revealed that nearly 80% of sampled birds were infected with malaria or related alveolates, underscoring the widespread prevalence of these parasites.

Explanation: The Malawi study indicated that closed-cup nesters, such as weavers and *Cisticola* species, exhibited higher infection rates with *Plasmodium* parasites compared to open-cup nesters.

Explanation: The primary mosquito vector for avian malaria in Hawaii is *Culex quinquefasciatus*, introduced to the islands in 1826, which falls within the 19th century.

Explanation: The introduction of *Culex quinquefasciatus* mosquitoes has had a devastating impact on native bird populations in Hawaii, contributing significantly to numerous extinctions.

Explanation: Cold temperatures restrict *Culex quinquefasciatus* mosquitoes to elevations below 5,000 feet (1,500 meters) due to inhibited larval development. However, there is concern regarding their potential adaptation to higher altitudes.

Explanation: There is significant concern regarding the potential adaptation of *Culex quinquefasciatus* mosquitoes to higher elevations in Hawaii, which could expose more native bird populations to avian malaria.

Explanation: The acute phase of avian malaria in susceptible birds is characterized by anemia due to red blood cell destruction, accompanied by general symptoms of illness such as weakness and depression. Severe cases may progress to coma and death.

Explanation: Avian malaria primarily affects passerines (perching birds), including native Hawaiian species such as honeycreepers and the Hawaiian crow. Susceptibility varies significantly among species.

Explanation: Native Hawaiian birds generally exhibit higher mortality rates from avian malaria compared to introduced species due to their greater susceptibility, posing severe conservation challenges for native avian fauna.

Explanation: *Plasmodium relictum* is implicated in restricting geographical ranges and causing extinctions of numerous Hawaiian bird species, particularly impacting forest birds in low-land habitats where the vector is prevalent.

Explanation: Recent California studies indicate rainfall patterns, rather than urbanization, exert a stronger influence on *Plasmodium* infections in birds like the Dark-eyed Junco. Conversely, infections by more specialized parasites, such as *Haemoproteus*, tend to decrease in highly urbanized settings.

Explanation: Avian malaria primarily affects passerines (perching birds), including native Hawaiian species such as honeycreepers and the Hawaiian crow. Susceptibility varies significantly among species.

Explanation: The primary mosquito vector, *Culex quinquefasciatus*, was introduced to Hawaii in 1826, predating the widespread impact of *Plasmodium relictum* on native bird populations, which became severe after the vector's establishment.

Explanation: Captive penguins in non-native environments are particularly vulnerable because they have not undergone co-evolution with avian malaria protozoa, thus lacking the inherent resistance observed in species with a long history of exposure.

Explanation: A 2015 study of Malawian bird fauna revealed that nearly 80% of sampled birds were infected with malaria or related alveolates, underscoring the widespread prevalence of these parasites.

Explanation: The Malawi study indicated that closed-cup nesters, such as weavers and *Cisticola* species, exhibited higher infection rates with *Plasmodium* parasites compared to other nesting types.

Explanation: The primary concern regarding the potential upward expansion of *Culex quinquefasciatus* mosquitoes in Hawaii is that they may reach higher elevations, thereby exposing the majority of the remaining native land bird populations to avian malaria.

Explanation: Avian malaria predominantly affects passerines, commonly known as perching birds.

Explanation: The introduction of *Culex quinquefasciatus* mosquitoes and avian malaria has had a profoundly devastating ecological impact on Hawaii's native bird populations, resulting in numerous extinctions.

Explanation: Sir Ronald Ross pursued avian malaria research as a more accessible model because studies on human malaria parasites proved challenging. The extensive diversity of avian malaria parasites offered a more manageable subject for his investigations.

Explanation: The study of avian malaria parasites is significantly complicated by the vast number of parasite lineages, the broad range of host species they can infect, and their capacity for host switching, rather than being simplified.

Explanation: Historically, avian malaria parasite species were classified based on limited morphological characteristics and host specificity. The advent of molecular phylogenetic data has since provided a more refined classification system.

Explanation: Molecular data has facilitated a shift from historical morphological classifications to a phylogenetic definition of parasite lineages, based on sequence divergence (e.g., cytochrome b gene) and host range, providing a more precise understanding.

Explanation: The MalAvi database serves as a repository for genetic sequence data of avian malaria parasites and related haemosporidians, not exclusively for *Plasmodium* species found in mammals.

Explanation: In molecular studies, a sequence divergence threshold of approximately 1.2% to 4% in specific genes, such as cytochrome b, is commonly employed to differentiate between distinct avian malaria parasite lineages, particularly in the absence of other definitive genetic markers.

Explanation: Molecular data indicates that *Plasmodium* species infecting birds and squamate reptiles form a distinct evolutionary clade, separate from the clade comprising species that infect mammals, suggesting divergent evolutionary pathways.

Explanation: Traditional classification of *Haemoproteus* relied on the type of insect vector involved in transmission, not solely on the bird host species infected.

Explanation: Genetic analyses of *Plasmodium relictum* have revealed significant variation between lineages found in the New World and the Old World, suggesting multiple introductions into avian populations across different regions.

Explanation: Sir Ronald Ross's primary discovery involved the transmission of malaria parasites to humans by mosquitoes. He later utilized avian malaria as an experimental model to further his research.

Explanation: In 1897, Ronald Ross conclusively proved the role of *Anopheles* mosquitoes in human malaria transmission by discovering the parasite within the stomach tissue of a mosquito that had fed on an infected patient.

Explanation: Studies suggest host switching is a more prevalent evolutionary phenomenon among avian haemosporidians, including avian malaria parasites, than speciation events, with adaptation to local hosts playing a secondary role.

Explanation: Historically, avian malaria parasite species were classified based on limited morphological characteristics and host specificity. This approach resulted in significant disagreement regarding species diversity and evolutionary relationships.

Explanation: Avian malaria served as a more accessible model for researchers like Dr. Ross due to the extensive diversity of its parasites, particularly when research on human malaria parasites presented significant challenges.

Explanation: The study of avian malaria parasites is significantly complicated by the extensive diversity of parasite lineages, the broad range of host species they can infect, and their demonstrated capacity for host switching.

Explanation: Molecular data has facilitated a shift from historical morphological classifications to a phylogenetic definition of parasite lineages, based on sequence divergence and host range, providing a more precise understanding.

Explanation: The MalAvi database functions as a public repository for genetic sequence data of avian malaria parasites and related haemosporidians, aiming to facilitate research into their vast diversity, particularly through sharing cytochrome b gene data.

Explanation: In molecular studies, a sequence divergence threshold of approximately 1.2% to 4% in specific genes, such as cytochrome b, is commonly employed to differentiate between distinct avian malaria parasite lineages, particularly in the absence of other definitive genetic markers.

Explanation: Molecular data indicates that *Plasmodium* species infecting birds and squamate reptiles form a distinct evolutionary clade, separate from the clade comprising species that infect mammals, suggesting divergent evolutionary pathways.

Explanation: Traditionally, the classification of *Haemoproteus* was determined based on the type of insect vector responsible for its transmission.

Explanation: Genetic analyses of *Plasmodium relictum* reveal significant differences between New World and Old World lineages, supporting the hypothesis of multiple introductions into avian populations across different regions.

Explanation: Sir Ronald Ross was awarded the Nobel Prize in Medicine in 1902 for his groundbreaking discovery demonstrating the role of mosquitoes in transmitting malaria parasites to humans.

Explanation: The primary strategy for controlling avian malaria focuses on managing and controlling mosquito populations, which serve as vectors, rather than direct treatment of infected birds.

Explanation: Managing feral pig populations aids mosquito control by reducing the number of wallows they create, which serve as ideal breeding grounds for mosquitoes, thus decreasing larval development sites.

Explanation: Effective measures around human dwellings to reduce mosquito breeding sites include emptying water from containers such as plant pots and old tires, thereby eliminating potential larval development habitats.

Explanation: Mosquito control efforts in Hawaii, including habitat reduction and larvicides, have not entirely eliminated the threat of avian malaria, which continues to pose a significant risk to native bird populations.

Explanation: A potential conservation strategy involves breeding birds naturally resistant to avian malaria, including collecting eggs from resistant individuals and reintroducing raised young to bolster population resistance and survival prospects.

Explanation: CRISPR gene editing technology has been proposed as a method for extirpating invasive mosquito populations in Hawaii, thereby controlling avian malaria spread.

Explanation: The primary recommended strategy for controlling avian malaria involves the management and control of mosquito populations, which serve as the disease vectors.

Explanation: Managing feral pig populations aids mosquito control by reducing the number of wallows they create, which serve as ideal breeding grounds for mosquitoes, thus decreasing larval development sites.

Explanation: CRISPR gene editing technology has been proposed as a method for extirpating invasive mosquito populations in Hawaii, thereby controlling avian malaria spread.