The dioecious and andromonoecious
Solanum
taxa (the “
S
.
dioicum
group”) of the Australian Monsoon Tropics have been the subject of phylogenetic and taxonomic study for decades, yet much of their basic biology is still unknown. This is especially true for plant-animal interactions, including the influence of fruit form and calyx morphology on seed dispersal. We combine field/greenhouse observations and specimen-based study with phylogenetic analysis of seven nuclear regions obtained via a microfluidic PCR-based enrichment strategy and high-throughput sequencing, and present the first species-tree hypothesis for the
S
.
dioicum
group. Our results suggest that epizoochorous trample burr seed dispersal (strongly linked to calyx accrescence) is far more common among Australian
Solanum
than previously thought and support the hypothesis that the combination of large fleshy fruits and endozoochorous dispersal represents a reversal in this study group. The general lack of direct evidence related to biotic dispersal (epizoochorous or endozoochorous) may be a function of declines and/or extinctions of vertebrate dispersers. Because of this, some taxa might now rely on secondary dispersal mechanisms (e.g. shakers, tumbleweeds, rafting) as a means to maintain current populations and establish new ones.
Immunocompromised individuals, including multiple sclerosis (MS) patients on certain immunotherapy treatments, are considered susceptible to complications from severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection and specific vaccination regimens have been recommended for suitable protection. MS patients receiving anti-CD20 therapy (aCD20-MS) are considered especially vulnerable due to acquired B-cell depletion and impaired antibody production in response to virus infection and COVID-19 vaccination. Here, the humoral and cellular responses are analyzed in a group of aCD20-MS patients (n=43) compared to a healthy control cohort (n=34) during the first 6 months after a 2-dose cycle mRNA-based COVID-19 vaccination. Both IgG antibodies recognizing receptor binding domain (RBD) from CoV-2 spike protein and their blocking activity against RBD-hACE2 binding were significantly reduced in aCD20-MS patients, with a seroconversion rate of only 23.8%. Interestingly, even under conditions of severe B-cell depletion and failed seroconversion, a significantly higher polyfunctional IFNγ+ and IL-2+ T-cell response and strong T-cell proliferation capacity were detected compared to controls. Moreover, no difference in T-cell response was observed between forms of disease (relapsing remitting- vs progressive-MS), anti-CD20 therapy (Rituximab vs Ocrelizumab) and type of mRNA-based vaccine received (mRNA-1273 vs BNT162b2). These results suggest the generation of a partial adaptive immune response to COVID-19 vaccination in B-cell depleted MS individuals driven by a functionally competent T-cell arm. Investigation into the role of the cellular immune response is important to identifying the level of protection against SARS-CoV-2 in aCD20-MS patients and could have potential implications for future vaccine design and application.
The deterioration in functions with age, a phenomenon termed senescence, is prevalent across the tree of life (Jones et al., 2014). Patterns of reproductive senescence vary widely among species with contrasting life histories, but, in general, life histories are considered to have evolved to optimize reproductive success given life expectancy (Williams, 1966; Gadgil and Bossert, 1970; Charnov et al., 2007) and the expected (i.e., seasonal and/or stochastic) progression of environments (Giesel, 1976). The survival-reproduction tradeoff is further complicated in hermaphroditic plants by the balance of male and female roles within individual flowers, as well as the possibility of self-fertilization. Sex allocation theory posits that predominantly self-fertilizing species (hereafter selfers) will allocate a greater proportion of reproductive resources toward fertilized ovule development to produce seeds, while outcrossing species (hereafter outcrossers) will divert more towards pollen production and delivery (Lloyd, 1987; Parker et al., 1995). Underlying both life history and sex allocation theories is the premise that resources are limited, and allocation to one function results in tradeoffs that incur fitness costs (Day and Aarssen, 1997). At the core of the differences between selfing and outcrossing mating systems is the form of pollen delivery. In particular, outcrossers often rely on visitation from animal vectors for pollen
Despite widespread evidence that biological invasion influences the biotic and abiotic soil environments, the extent to which each of these pathways underpins the effects of invasion on native plant traits and performance is unknown. Leveraging a long-term (14-yr) manipulative field experiment, we show that an allelochemical-producing invader, Alliaria petiolata, affects native plants through biotic mechanisms, altering the soil fungal community composition, with no apparent shifts in soil nutrient availability. These changes in belowground soil fungal communities resulted in a high cost of resource uptake for native forest perennial herbs and a shift in functional traits linked to their carbon and nutrient economies. Furthermore, we illustrate that some species in the invaded community compensate for high nutrient costs by reducing nutrient uptake and maintaining photosynthesis by expending more water. This demonstrates a trade-off in trait investment that increases nutrient use efficiency as nutrient costs increase. Our results show that invasion-induced disruptions in the soil fungal community belowground can cascade to affect aboveground plant communities via shifts in physiological traits needed to maintain plant water and nutrient economies. These complex above-belowground linkages suggest that plant invasions should be evaluated at the system-level to fully understand and predict their impact on native plants and communities.
The dioecious and andromonoecious Solanum taxa (previously described as the “S. dioicum group”) of the Australian Monsoon Tropics have been the subject of phylogenetic and taxonomic study for decades, yet much of their basic biology is still unknown. This is especially true for plant-animal interactions, including the influence of fruit form and calyx morphology on seed dispersal. We combine field/greenhouse observations and specimen-based study with phylogenetic analysis of seven nuclear regions obtained via a microfluidic PCR-based enrichment strategy and high-throughput sequencing, and present the first intron-containing nuclear gene dataset in the genus Solanum and the first species-tree hypothesis for the S. dioicum group. Our results suggest that epizoochorous trample burr seed dispersal (strongly linked to calyx accrescence) is far more common among Australian Solanum than previously thought and support the hypothesis that the combination of large fleshy fruits and endozoochorous dispersal represents a reversal in this study group. The general lack of direct evidence related to biotic dispersal (epizoochorous or endozoochorous) may be a function of declines and/or extinctions of vertebrate dispersers. Because of this, some taxa might now rely on secondary dispersal mechanisms (e.g. shakers, tumbleweeds, rafting) as a means to maintain current populations and establish new ones.
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