Sp1 sites in the noncoding control region of BK polyomavirus are key regulators of bidirectional viral early and late gene expression.

UNLABELLED: In kidney transplant patients with BK polyomavirus (BKPyV) nephropathy, viral variants arise bearing rearranged noncoding control regions (rr-NCCRs) that increase viral early gene expression, replicative fitness, and cytopathology. rr-NCCRs result from various deletions and duplications of archetype NCCR (ww-NCCR) sequences, which alter transcription factor binding sites (TFBS). However, the role of specific TFBS is unclear. We inactivated 28 TFBS in the archetype NCCR by selective point mutations and examined viral gene expression in bidirectional reporter constructs. Compared to the archetype, group 1 mutations increased viral early gene expression similar to rr-NCCR and resulted from inactivating one Sp1 or one Ets1 TFBS near the late transcription start site (TSS). Group 2 mutations conferred intermediate early gene activation and affected NF1, YY1, and p53 sites between early and late TSS. Group 3 mutations decreased early and late gene expression and included two other Sp1 sites near the early TSS. Recombinant viruses bearing group 1 NCCRs showed increased replication in human renal epithelial cells similar to clinical rr-NCCR variants. Group 2 and 3 viruses showed intermediate or no replication, respectively. A literature search revealed unnoticed group 1 mutations in BKPyV nephropathy, hemorrhagic cystitis, and disseminated disease. IMPORTANCE: The NCCRs of polyomaviruses mediate silent persistence of the viral genome as well as the appropriately timed (re)activation of the viral life cycle. This study indicates that the basal BKPyV NCCR is critically controlled by a hierarchy of single TFBS in the archetype NCCR that direct, modulate, and execute the bidirectional early and late viral gene expression. The results provide new insights into how BKPyV NCCR functions as a viral sensor of host cell signals and shed new light on how transcription factors like Sp1 control bidirectional viral gene expression and contribute to replication and pathology.

A bispecific HER2-targeting FynomAb with superior antitumor activity and novel mode of action.

Upregulation of HER2 is a hallmark of 20% to 30% of invasive breast cancers, rendering this receptor an attractive target for cancer therapy. Although HER2-targeting agents have provided substantial clinical benefit as cancer therapeutics, there is a need for the development of new agents aiming at circumventing anti-HER2 resistance. On the basis of the approved antibody pertuzumab, we have created a panel of bispecific FynomAbs, which target two epitopes on HER2. FynomAbs are fusion proteins of an antibody and a Fyn SH3-derived binding protein. One bispecific FynomAb, COVA208, was characterized in detail and showed a remarkable ability to induce rapid HER2 internalization and apoptosis in vitro. Moreover, it elicited a strong inhibition of downstream HER2 signaling by reducing HER2, HER3, and EGFR levels in vitro and in vivo. Importantly, COVA208 demonstrated superior activity in four different xenograft models as compared with the approved antibodies trastuzumab and pertuzumab. The bispecific FynomAb COVA208 has the potential to enhance the clinical efficacy and expand the scope of HER2-directed therapies, and delineates a paradigm for designing a new class of antibody-based therapeutics for other receptor targets.