Capillary Force Lithography for Cardiac Tissue Engineering

Cardiovascular disease remains the leading cause of death worldwide¹. Cardiac tissue engineering holds much promise to deliver groundbreaking medical discoveries with the aims of developing functional tissues for cardiac regeneration as well as in vitro screening assays. However, the ability to create high-fidelity models of heart tissue has proven difficult. The heart’s extracellular matrix (ECM) is a complex structure consisting of both biochemical and biomechanical signals ranging from the micro- to the nanometer scale². Local mechanical loading conditions and cell-ECM interactions have recently been recognized as vital components in cardiac tissue engineering^3-5.A large portion of the cardiac ECM is composed of aligned collagen fibers with nano-scale diameters that significantly influences tissue architecture and electromechanical coupling². Unfortunately, few methods have been able to mimic the organization of ECM fibers down to the nanometer scale. Recent advancements in nanofabrication techniques, however, have enabled the design and fabrication of scalable scaffolds that mimic the in vivo structural and substrate stiffness cues of the ECM in the heart^6-9.Here we present the development of two reproducible, cost-effective, and scalable nanopatterning processes for the functional alignment of cardiac cells using the biocompatible polymer poly(lactide-co-glycolide) (PLGA)⁸ and a polyurethane (PU) based polymer. These anisotropically nanofabricated substrata (ANFS) mimic the underlying ECM of well-organized, aligned tissues and can be used to investigate the role of nanotopography on cell morphology and function^10-14.Using a nanopatterned (NP) silicon master as a template, a polyurethane acrylate (PUA) mold is fabricated. This PUA mold is then used to pattern the PU or PLGA hydrogel via UV-assisted or solvent-mediated capillary force lithography (CFL), respectively^15,16. Briefly, PU or PLGA pre-polymer is drop dispensed onto a glass coverslip and the PUA mold is placed on top. For UV-assisted CFL, the PU is then exposed to UV radiation (λ = 250-400 nm) for curing. For solvent-mediated CFL, the PLGA is embossed using heat (120 °C) and pressure (100 kPa). After curing, the PUA mold is peeled off, leaving behind an ANFS for cell culture. Primary cells, such as neonatal rat ventricular myocytes, as well as human pluripotent stem cell-derived cardiomyocytes, can be maintained on the ANFS².     

Evaluation of a small-scale method for the extraction of the K88 antigen from enterotoxigenic Escherichia coli

A small-scale method for the extraction of the K88 major fimbrial subunit from enterotoxigenic Escherichia coli (ETEC) based on heat extraction has been developed. Variation in the buffer composition, time and temperature of extraction had negligible effect on the subsequent SDS-PAGE profile. There was, however, a correlation between the pH of the extraction buffer and the ensuing amount of K88 released. Reduction of the pH from 7 to 4 reduced by six-fold the amount of K88 released from the cells. We suggest that the relative stability of the K88 fimbriae at acid pH may influence the site of infection by ETEC in the intestine.     

Mice: Pregnancy termination, lactation, and aggression

Hysterectomy on the 14th day of gestation in combination with the immediate and repetitive presentation of 1-day-old foster young produced lactation and fighting behavior toward adult males. The fighting behavior was comparable to that displayed by normally parturient mice. Hysterectomy alone or the presentation of pups alone initiated neither lactation nor fighting. Hysterectomy performed prior to the 12th day of gestation plus the presentation of foster young also did not initiate lactation or fighting. Ovariectomy performed in conjunction with hysterectomy on the 14th day of pregnancy together with the presentation of young produced lactation but not fighting behavior, thus suggesting that fighting and lactation are controlled by somewhat different hormonal mechanisms.     

Helical Organization of Blood Coagulation Factor VIII on Lipid Nanotubes

Cryo-electron microscopy (Cryo-EM)¹ is a powerful approach to investigate the functional structure of proteins and complexes in a hydrated state and membrane environment².Coagulation Factor VIII (FVIII)³ is a multi-domain blood plasma glycoprotein. Defect or deficiency of FVIII is the cause for Hemophilia type A - a severe bleeding disorder. Upon proteolytic activation, FVIII binds to the serine protease Factor IXa on the negatively charged platelet membrane, which is critical for normal blood clotting⁴. Despite the pivotal role FVIII plays in coagulation, structural information for its membrane-bound state is incomplete⁵. Recombinant FVIII concentrate is the most effective drug against Hemophilia type A and commercially available FVIII can be expressed as human or porcine, both forming functional complexes with human Factor IXa^6,7.In this study we present a combination of Cryo-electron microscopy (Cryo-EM), lipid nanotechnology and structure analysis applied to resolve the membrane-bound structure of two highly homologous FVIII forms: human and porcine. The methodology developed in our laboratory to helically organize the two functional recombinant FVIII forms on negatively charged lipid nanotubes (LNT) is described. The representative results demonstrate that our approach is sufficiently sensitive to define the differences in the helical organization between the two highly homologous in sequence (86% sequence identity) proteins. Detailed protocols for the helical organization, Cryo-EM and electron tomography (ET) data acquisition are given. The two-dimensional (2D) and three-dimensional (3D) structure analysis applied to obtain the 3D reconstructions of human and porcine FVIII-LNT is discussed. The presented human and porcine FVIII-LNT structures show the potential of the proposed methodology to calculate the functional, membrane-bound organization of blood coagulation Factor VIII at high resolution.     

Polymorphism and inheritance of swine small intestinal receptors mediating adhesion of three serological variants of Escherichia coli-producing K88 pilus antigen

Summary. Brush borders, enterocytes, or both preparations obtained from the small intestine of 345 pedigreed pigs, carrying components of seven breeds, were tested by adhesion assay in vitro with 6–32 enteropathogenic Escherichia coli strains, each expressing one of the three K88 pilus antigens, K88ab, K88ac and K88ad. With few exceptions, all pigs were classified as belonging to one of four adhesion phenotypes: I – corresponding to K88ab(-),ac(-),ad(-); II – K88ab(-),ac(+),ad(+); III – K88ab(+),ac(+),ad(-); and IV – K88ab(+),ac(+),ad(+). The non-adhering phenotype I was found to be the most frequent among the pigs tested, with the exception of one commercial herd, and this phenotype seems to be inherited as a recessive trait. The remaining three phenotypes are adhering, or are susceptible to adherence by one K88 variant, K88ad (phenotype II), by two variants, K88ab,ac (phenotype III), or by all three K88 variants, K88ab,ac,ad (phenotype IV). Phenotype II was found to be at low frequency, whereas III and IV occurred with similar frequencies. While the prevailing phenomenon was the bacterial adhesion to all, or none, of the brush borders, some pigs exhibited both adhering and non-adhering brush borders, a mixed adherence phenotype. Preliminary segregation data, obtained from the F1 generation, seem to indicate that phenotypes III and IV correspond to two haplotypes with genes at two or three closely linked loci respectively. An alternative hypothesis is that the phenotypes [II and IV are expressions of alleles at a single locus, each allele specifying a receptor able to bind two or three different serological types of K88 E. coli.     

A novel method for increasing bacterial cellular yields of a fimbrial subunit polypeptide

Abstract An in-depth understanding of the genetic organisation of the K88 adhesion fimbriae determinant has been used to construct novel recombinant plasmids which direct the expression of high levels of K88 fimbriae suitable for use in vaccine preparations when harboured by Escherichia coli K12. This was achieved by placing the fimbrial subunit polypeptide cistron under the control of a powerful E. coli promoter while leaving the expression of the other cistrons encoded within the K88 determinant under the control of a separate promoter. This methodology could be used as a general approach to construct strains expressing high levels of other bacterial fimbriae.     

Better Cryo-EM Specimen Preparation: How to Deal with the Air–Water Interface?

Cryogenic electron microscopy (cryo-EM) is now one of the most powerful and widely used methods to determine high-resolution structures of macromolecules. A major bottleneck of cryo-EM is to prepare high-quality vitrified specimen, which still faces many practical challenges. During the conventional vitrification process, macromolecules tend to adsorb at the air–water interface (AWI), which is known unfriendly to biological samples. In this review, we outline the nature of AWI and the problems caused by it, such as unpredictable or uneven particle distribution, protein denaturation, dissociation of complex and preferential orientation. We review and discuss the approaches and underlying mechanisms to deal with AWI: 1) Additives, exemplified by detergents, forming a protective layer at AWI and thus preserving the native folds of target macromolecules. 2) Fast vitrification devices based on the idea to freeze in-solution macromolecules before their touching of AWI. 3) Thin layer of continuous supporting films to adsorb macromolecules, and when functionalized with affinity ligands, to specifically anchor the target particles away from the AWI. Among these supporting films, graphene, together with its derivatives, with negligible background noise and mechanical robustness, has emerged as a new generation of support. These strategies have been proven successful in various cases and enable us a better handling of the problems caused by the AWI in cryo-EM specimen preparation.