Structural Basis for Receptor Selectivity by the Whitewater Arroyo Mammarenavirus.

Whitewater Arroyo virus belongs to the "New World" group of mammarenaviruses that reside in rodent reservoirs and are prevalent in North and South Americas. Clades B and A/B of New World mammarenaviruses use transferrin receptor 1 (TfR1) for entry. While all of these viruses use rodent-derived TfR1 orthologs, some can also use the human-TfR1 and thereby infect humans. Although we have structural information for TfR1 recognition by pathogenic virus, we do not know what the structural differences are between the receptor-binding domains of pathogenic and non-pathogenic viruses that allow some but not all viruses to utilize the human receptor for entry. The poor understanding of the molecular determinants of mammarenavirus host range, and thus pathogenicity, is partly due to the low sequence similarity between the receptor-binding domains from these viruses and the limited available structural information that preclude the use of modeling approaches. Here we present the first crystal structure of a receptor-binding domain of a non-pathogenic clade A/B mammarenavirus. This structure reveals the magnitude of structural differences within the receptor-binding domains of TfR1-tropic viruses. Our structural and sequence analyses indicate that the same structural incompatibilities with the human receptor equally affect both pathogenic and non-pathogenic mammarenaviruses. Non-pathogenic viruses do not have specific structural elements that prevent them from using the human receptor. Instead, the ability to utilize the human receptor directly depends on the extent of weak interactions throughout the receptor-binding site that in some viruses are sufficiently strong to overcome the structural incompatibilities.

Role of LAMP1 Binding and pH Sensing by the Spike Complex of Lassa Virus.

To effectively infect cells, Lassa virus needs to switch in an endosomal compartment from its primary receptor, α-dystroglycan, to a protein termed LAMP1. A unique histidine triad on the surface of the receptor-binding domain from the glycoprotein spike complex of Lassa virus is important for LAMP1 binding. Here we investigate mutated spikes that have an impaired ability to interact with LAMP1 and show that although LAMP1 is important for efficient infectivity, it is not required for spike-mediated membrane fusion per se Our studies reveal important regulatory roles for histidines from the triad in sensing acidic pH and preventing premature spike triggering. We further show that LAMP1 requires a positively charged His230 residue to engage with the spike complex and that LAMP1 binding promotes membrane fusion. These results elucidate the molecular role of LAMP1 binding during Lassa virus cell entry and provide new insights into how pH is sensed by the spike. IMPORTANCE: Lassa virus is a devastating disease-causing agent in West Africa, with a significant yearly death toll and severe long-term complications associated with its infection in survivors. In recent years, we learned that Lassa virus needs to switch receptors in a pH-dependent manner to efficiently infect cells, but neither the molecular mechanisms that allow switching nor the actual effects of switching were known. Here we investigate the activity of the viral spike complex after abrogation of its ability to switch receptors. These studies inform us about the role of switching receptors and provide new insights into how the spike senses acidic pH.