Native HA Research Articles

Electrostatically self-assembled gold nanorods with sulfated hyaluronic acid for targeted photothermal therapy for CD44-positive tumors

Gold nanorods (GNR) produce heat upon irradiation with near-infrared light, enabling a tumor-targeted photothermal therapy. In this study, we prepared GNR coated with sulfated hyaluronic acid (sHA) with a binding affinity for CD44 via electrostatic interactions to deliver GNR to tumors efficiently and stably, and evaluated their usefulness for photothermal therapy. Cationic GNR modified with trimethylammonium groups electrostatically interacted with native HA or sHA with varying degrees of sulfation to form complexes. While GNR/HA was unstable in saline, GNR/sHA maintained the absorbance peak in the near-infrared region, particularly for GNR/sHA with higher degrees of sulfation. GNR/sHA exhibited an intense photothermal effect upon irradiation with near-infrared light. Furthermore, in vitro and in vivo studies revealed that GNR coated with sHA containing approximately 1.2 sulfated groups per HA unit could accumulate in CD44-positive tumors via an HA-specific pathway. These findings indicate the effectiveness of GNR/sHA as a tumor-targeted photothermal therapeutic agent.

Inhibition of Pro-Fibrotic Molecules Expression in Idiopathic Pulmonary Fibrosis-Derived Lung Fibroblasts by Lactose-Modified Hyaluronic Acid Compounds.

Idiopathic pulmonary fibrosis (IPF) is a chronic inflammatory and fibrotic pathological condition with undefined effective therapies and a poor prognosis, partly due to the lack of specific and effective therapies. Galectin 3 (Gal-3), a pro-fibrotic ß-galactoside binding lectin, was upregulated in the early stages of the pathology, suggesting that it may be considered a marker of active fibrosis. In the present in vitro study, we use Hylach®, a lactose-modified hyaluronic acid able to bind Gal-3, to prevent the activation of lung myofibroblast and the consequent excessive ECM protein cell expression. Primary human pulmonary fibroblasts obtained from normal and IPF subjects activated with TGF-β were used, and changes in cell viability, fibrotic components, and pro-inflammatory mediator expression at both gene and protein levels were analyzed. Hylach compounds with a lactosylation degree of about 10% and 30% (Hylach1 and Hylach 2), administrated to TGF-β-stimulated lung fibroblast cultures, significantly downregulated α-smooth muscle actin (α-SMA) gene expression and decreased collagen type I, collagen type III, elastin, fibronectin gene and protein expression to near baseline values. This anti-fibrotic activity is accompanied by a strong anti-inflammatory effect and by a downregulation of the gene expression of Smad2 for both Hylachs in comparison to the native HA. In conclusion, the Gal-3 binding molecules Hylachs attenuated inflammation and TGF-β-induced over-expression of α-SMA and ECM protein expression by primary human lung fibroblasts, providing a new direction for the treatment of pulmonary fibrotic diseases.

Structuring supramolecular hyaluronan hydrogels via peptide self-assembly for modulating the cell microenvironment.

The use of synthetic extracellular matrices (ECMs) in fundamental in vitro cell culture studies has been instrumental for investigating the interplay between cells and matrix components. To provide cells with a more native environment in vitro, it is desirable to design matrices that are biomimetic and emulate compositional and structural features of natural ECMs. Here, the supramolecular fabrication of peptide-hyaluronan (HA) hydrogels is presented as potential ECM surrogates, combining native HA and rationally designed cationic amphipatic peptides [(KI)nK, lysine (K), isoleucine (I), n​=​2-6] whose mechanical properties and microstructure are tunable by the peptide sequence. (KI)nK peptides adopt β-sheet configuration and self-assemble into filamentous nanostructures triggered by pH or ionic strength. The self-assembly propensity of (KI)nK peptides increases with the sequence length, forming single phase hydrogels (shorter peptides) or with phase separation (longer peptides) in presence of the anionic polyelectrolyte HA through electrostatic complexations. The gel phase formed in (KI)nK-HA complexes exhibits viscoelastic behavior and triggers the formation of human mesenchymal stem cell (MSC) spheroids which disassemble over the time. It is anticipated that these (KI)nK-HA hydrogels with tunable physical and biochemical properties offer a promising platform for in vitro applications and in stem cell therapy.

A New Approach toward the Management of Patients with Premature Skin Aging Using the Predictor Effect

Our study aimed to develop a comprehensive approach to the management of patients with involutional skin changes, considering the predictors of premature skin aging. The study included two stages, whereby 78 women with no history of aesthetic procedures that could have affected their perceived age were examined. In the first stage, we examined factors associated with premature skin aging. In the second stage, a blind, comparative placebo-controlled study of the effectiveness of intradermal injections for the treatment of involutional skin changes was conducted. Parameters reflecting skin aging were identified. The sum of these parameters could be used to diagnose premature skin aging in patients with no history of aesthetic treatment. For other patients, we developed indicators that can be applied to determine whether there is a risk of premature skin aging. Patients with premature aging have an increased risk of adverse events, such as impaired regeneration and wound healing, postprocedural hematomas, etc. For the correction of involutional skin changes in patients with premature aging, the collagen product (Collost) had the greatest clinical efficiency and the greatest patient satisfaction. A complex product based on HA (Teosyal Redensity 1) had comparable efficiency, with slightly less patient satisfaction. The product based on native HA (Hyon 1.8%) had low efficiency in the group of patients with premature aging and high efficiency in the group of patients with normal aging.

Herbage mass and allowance and animal genotype affect daily herbage intake, productivity, and efficiency of beef cows grazing native subtropical grassland

The beef sector in Campos grasslands must increase animal productivity without external inputs, while reducing environmental impact. The objective of this study was to estimate herbage intake (g/metabolic body weight [MBW]/d) of straightbred (Hereford/Angus) and crossbred (F1 of Hereford × Angus) beef cows grazing subtropical native grassland with High and Low herbage allowance (HA, 5 vs. 3 kg DM/kg bodyweight [BW]) during gestation and lactation and its relationship with biological efficiency of cow-calf productivity. Herbage intake (estimated via n-alkanes C32:C33 ratio) was measured during early (Ge1, -163 d prior calving) and mid to late [Gm1 (-83) and Gm2 (-90 d prior calving)] gestation and lactation (L0, L1, and L2, 60, 47, and 31d following calving) periods in 24 to 36 cows, selected to create 8 groups (4 per block) of HA × cow genotype treatment. Cows grazed native grassland year-round, under High and Low HA (except in winter). We analyzed the effect of cow genotype (straightbred vs. crossbred cows) and HA (High vs. Low) on herbage mass and height, daily herbage intake rate (DMI), cow body condition score (BCS), calf average daily gain (ADG) and BW at weaning (BWW) and g of calf weaned/kg DMI. High allowance improved DMI during lactation periods (High 115.6 vs. Low 94.1 ± 5.3; P < 0.05 g/MBW/d). Crossbred cows decreased DMI during gestation (Crossbred 81 vs. Straightbred 94 ± 4.3; P = 0.05 g/MBW/d) compared with straightbred cows. Crossbred and High HA improved biological efficiency, 40.0 vs. 26.2 and 36.0 vs. 29.7 g of calf/kg DMI, respectively. High allowance increased herbage mass and sites with greater canopy height that allow greater DMI, positively associated with cow BCS at weaning, calf ADG, BWW, and g of calf/kg DMI. Crossbred cows reduced DMI during gestation showing no greater annual DMI. Animal productivity and biological efficiency can be improved using High HA and crossbred cows, which should decrease the environmental impact of cow-calf systems.

Hemagglutinin head-specific responses dominate over stem-specific responses following prime boost with mismatched vaccines.

Broadly neutralizing Abs targeting the HA stem can provide broad protection against different influenza subtypes, raising the question of how best to elicit such Abs. We have previously demonstrated that vaccination with pandemic live-attenuated influenza vaccine (pLAIV) establishes immune memory for HA head-specific Abs. Here, we determine the extent to which matched versus mismatched LAIV-inactivated subunit vaccine (IIV) prime-boost vaccination elicits stem-specific memory B cells and Abs. We vaccinated African green monkeys with H5N1 pLAIV-pIIV or H5N1 pLAIV followed by seasonal IIV (sIIV) or with H5N1 pLAIV alone and measured Abs and HA-specific B cell responses. While we observed an increase in stem-specific memory B cells, head-specific memory B cell responses were substantially higher than stem-specific responses and were dominant even following boost with mismatched IIV. Neutralizing Abs against heterologous influenza viruses were undetectable. Head-specific B cells from draining lymph nodes exhibited germinal center markers, while stem-specific B cells found in the spleen and peripheral blood did not. Thus, although mismatched prime-boost generated a pool of stem-specific memory B cells, head-specific B cells and serum Abs substantially dominated the immune response. These findings have implications for including full-length native HA in prime-boost strategies intended to induce stem-specific Abs for universal influenza vaccination.

Co-Spray-Dried Urea Cross-Linked Hyaluronic Acid and Sodium Ascorbyl Phosphate as Novel Inhalable Dry Powder Formulation

The pathogenesis and progression of several lung disorders is propagated by inflammatory and oxidative processes, which can be controlled by adjunctive inhaled therapies. The present study aimed to develop an inhalable dry powder formulation consisting of co-spray-dried urea-crosslinked hyaluronic acid and sodium ascorbyl phosphate (SD HA-CL–SAP), a novel combination which was recently shown to possess anti-inflammatory, antioxidant, and wound healing properties. Native HA and SAP were co-spray dried (SD HA–SAP) and evaluated as control formulation. Yield (Y%) and encapsulation efficiency (EE%) were 67.0 ± 4.8% and 75.5 ± 7.2% for SD HA–SAP, 70.0 ± 1.5% and 66.5 ± 5.7% for SD HA-CL–SAP, respectively. Both formulations were shown to be suitable for lung delivery in terms of morphology, particle size (median volumetric diameter ∼ 3.4 μm), physical and thermal stability, in vitro aerosol performance - respirable fraction: 30.5 ± 0.7% for SD HA–SAP and 35.3 ± 0.3% for SD HA-CL–SAP. SAP release was investigated using Franz cells and air-interface Calu-3 cell model (>90% of SAP transported within 4 h). The innovative SD HA-CL–SAP formulation holds potential as inhalable dry powder for the treatment of inflammatory lung disorders.

Cryo-EM Tomographic Analysis of a Universal Influenza Virus Vaccine Candidate

Influenza viruses cause hundreds of millions of infections every year, and vaccines currently in use need to be reformulated annually due to the rapid mutation potential of these viruses. A universal influenza vaccine would alleviate the need for the yearly vaccine. Chimeric hemagglutinin (cHA) proteins are currently in development as potential universal influenza virus vaccines based on the idea that when the immune system is sequentially exposed to HA proteins that express the same stalk, but different head domains, the resulting antibody response will be directed toward the conserved stalk domain instead of the rapidly mutating head domain. This vaccination strategy increases the body's production of broadly neutralizing antibodies. Due to the conformational nature of stalk epitopes, it is necessary to ensure that these epitopes remain correctly folded in the chimeric proteins, yet no prior structural information about cHA proteins exists. We used cryo-electron tomography to determine structures of a virus-bound cHA, cH5/1, comprising an H1 stalk and an H5 head domain. Compared to native H1 or H5 HA, the cHA shows a more open head domain with clear separation between HA monomers. The cHA structure also shows a dramatic rotation between the stalk and head domains compared to the native structures. Viruses expressing cH5/1 HA also had a significantly higher density of HA on the viral surface than those expressing native HA. Despite these dramatic differences, cH5/1 retains its antibody-binding function with both head and stalk-targeting antibodies, suggesting a surprising plasticity in HA protein structure that may benefit future vaccine design.

Sulfated hyaluronan affects fibronectin matrix assembly by human bone marrow stromal cells

Event Abstract Back to Event Sulfated hyaluronan affects fibronectin matrix assembly by human bone marrow stromal cells Sarah Vogel1, Stephanie Moeller2, Simon Arnoldini3, Sergey Samsonov4, Matthias Schnabelrauch2, Viola Vogel3 and Ute Hempel1 1 TU Dresden, Institute of Physiological Chemistry, Carl Gustav Carus Faculty of Medicine, Germany 2 Innovent e. V, Biomaterials Department, Germany 3 ETH Zurich, Laboratory of Applied Mechanobiology, Department of Health Science and Technology, Switzerland 4 Tu Dresden, Structural Bioinformatics, Biotec, Germany Introduction: In the bone marrow niche, human bone marrow stromal cells (hBMSC) are surrounded by extracellular matrix (ECM) containing CaP, collagen I, fibronectin (FN) and sulfated glycosaminoglycans (sGAG). Synthetically sulfated hyaluronan (sHA1) has been shown to support osteogenesis of hBMSC[1] and to inhibit osteoclast formation[2]. Osteoblasts synthesize large amounts of FN and deposit the protein into the bone matrix. FN is secreted as a 440 kDa dimeric glycoprotein with binding domains for cells via integrins and several ECM components like collagen I and heparin. The assembly of FN fibrils is a cell-mediated process and depends on integrin binding[3]. In this study we describe the effects of sHA1 on FN matrix assembly by hBMSC in vitro. Materials and Methods: The sulfation of native HA was performed with SO3/DMF and resulted in sHA1with a sulfation degree of 1.3 and a molecular weight of 26,600 g/mol[4]. Fluorescence-labelled HA and sHA1 were obtained with Atto565-NH2 using side-on modification[2]. Human BMSC were cultured in DMEM with 10% FCS supplemented with 200 µg HA or sHA1 / ml[1]. For characterization of FN matrix at day 8, immunofluorescence staining was performed[1]. The influence of HA and sHA1 on FN matrix assembly was characterized using FRET-assay[5]. Results and Discussion: Immunofluorescence staining indicated a colocalization of Atto565-sHA1 and FN fibrils (figure 1C) but no colocalization of Atto565-HA and FN (figure 1B). In silico studies supported the electrostatic interaction between sHA1 and heparin binding sites which might affect growth factor binding and FN fibril formation. Figure 1: Immunofluorescence staining of hBMSC at day 8 (A) and after permanent treatment with Atto565-HA (B) or Atto565-sHA1 (C). FN (green), Nuclei (blue). It was found that sHA1 affected FN matrix assembly as more and thinner FN fibrils were formed in comparison to untreated control and HA (figure 1). The effect of sHA1 on FN matrix assembly was more detailed characterized by FRET-analysis which confirmed FN-stretching in the presence of sHA1 similar to heparin[5]. Besides its effects on FN assembly, sHA1 induced FN protein and influenced its remodeling by reducing activity of matrix metalloproteinases and increasing the formation of tissue inhibitor of metalloproteinase-3 (TIMP-3)[6],[7]. Conclusion: The present study shows one putative mechanism how sHA1 influences ECM assembly and remodelling. Our findings contribute to clarify the impact of sHA1 on molecular mechanisms in hBMSC. Deutsche Forschungsgemeinschaft TRR67 (projects B1, A7, Z3)

Biomimetic multidirectional scaffolds for osteochondral repair by sequential freeze casting

Event Abstract Back to Event Biomimetic multidirectional scaffolds for osteochondral repair by sequential freeze casting Drew Clearfield1 and Mei Wei1 1 University of Connecticut, Department of Materials Science and Engineering, Institute of Materials Science, United States Introduction: By the year 2030, osteoarthritis is expected to affect 67 million Americans[1]. Osteoarthritis commonly leads to the creation of osteochondral lesions[2]. These lesions disrupt the unique zonal organization of osteochondral extracellular matrix, which proves vital to its function[3]. There exists a need for tissue engineering strategies to induce the regeneration of new tissue that recapitulates this zonal organization and corresponding functionality. In the current work, a sequential freeze casting process is detailed that allows for the fabrication of multi-zonal collagen-based scaffolds that mimic three zonal features of native osteochondral extracellular matrix: the superficial zone (SZ), the transition zone (TZ), and the deep zone (DZ) morphologies [1], zonal pore size gradient [2], and zone-specific compositions [3] of articular cartilage and subchondral bone in a single construct. To mimic the zonal structure, a multizonal scaffold has been designed through a novel sequential freezing process for osteochondral defect repair. Zonal anisotropy is created through two stages of unidirectional freezing. Zone-specific pore size is controlled through applied cooling rate and zone-specific composition is controlled by adjusting initial suspension formulations. Methods: Sequential freeze casting was performed to create multizonal collagen (Col) and collagen-hyaluronic acid (Col-HYA)/collagen-hydroxyapatite (Col-HA) composite scaffolds. For collagen-only scaffolds, 2 wt% type I collagen was homogenized in deionized water, degased, and unidirectionally frozen. The frozen structure was flipped 90º, partially melted, and a second collagen suspension was loaded and unidirectionally frozen atop the first. Sequentially frozen scaffolds were lyophilized at -40ºC for 3 days, crosslinked with 2% EDC (1-ethyl-3-(3-dimethylaminopropyl)carbodiimide hydrochloride):NHS (N-hydroxysuccinimide) (1:0.25 molar ratio), and lyophilized for another 3 days. The effect of cooling rate on zonal pore size was investigated. SEM analysis was performed to view zonal morphologies (longitudinal sections) and quantify pore sizes (transverse sections). To further mimic the zonal composition of native osteochondral extracellular matrix, HYA and HA was added to the collagen suspensions and the scaffolds were prepared using the approached described above. A Col-HYA (1.8 wt% Col, 0.2 wt% HYA) suspension was first unidirectionally frozen at 2ºC/min. A second Col-HYA slurry of increased HYA and decreased Col content was frozen 90º to the first at 0.5ºC/min, where a third Col-HA slurry was layered atop. Results and Discussion: SEM analysis reveals three distinct zones of collagen fiber orientation seamlessly integrated together (Figure 1). A 200-300 µm transition region of isotropic collagen integrates between two zones of unidirectionally aligned fibers, perpendicular to one another. Pore size quantification revealed a trend of increasing pore sizes through the depth of the scaffold. Zonal pore sizes were controlled by the applied cooling rate. Quicker cooling led to the formation of smaller pores, while slower cooling promoted larger pores. Fig. 1: Scanning electron micrograph of collagen-based multizonal scaffolds. SZ - superficial zone, TZ - transition zone, DZ - deep zone. Conclusions: Sequentially freeze cast multizonal collagen-based scaffolds were fabricated that mimic the zone-specific collagen fiber orientation, pore size, and composition present in native osteochondral tissue. The authors would like to thank NSF grants (CBET-1133883 and CBET-1347130) for their support

Influenza virus hemagglutinin as a vaccine antigen produced in bacteria.

Recombinant subunit vaccines based on hemagglutinin proteins produced in bacteria (bacterial HAs) are promising candidates for enhancing the supply of vaccines against influenza, especially for a pandemic. Over 20 years after the failure to obtain the antigen with native HA characteristics in the early 1980's, there are increasing data on successful production of HA proteins in bacteria. The vast majority of bacterial HAs have been based on the HA1 subunit of HA expressed separately or as a component of conjugate vaccines, but those based on the ectodomain and the HA2 subunit have also been reported. The most of HAs have been efficiently expressed as insoluble aggregates called inclusion bodies. Refolded and purified proteins were extensively studied for structure, the ability to bind to sialic acid-containing receptors, antigenicity, immunogenicity and efficacy. The results from these studies contradict the view that glycosylation determines the correct structure of the hemagglutinin, as they proved that bacterial HAs can be valuable vaccine antigens when appropriate folding and purification methods are applied to rationally designed proteins. The best evidence for success in bacterial production of protective HA is that vaccines based on proprietary Toll-like Receptor (VaxInnate) and bacteriophage Qβ-VLPs (Cytos Biotechnology) technologies have been advanced to clinical studies.

Influenza hemagglutinin stem-fragment immunogen elicits broadly neutralizing antibodies and confers heterologous protection.

Influenza hemagglutinin (HA) is the primary target of the humoral response during infection/vaccination. Current influenza vaccines typically fail to elicit/boost broadly neutralizing antibodies (bnAbs), thereby limiting their efficacy. Although several bnAbs bind to the conserved stem domain of HA, focusing the immune response to this conserved stem in the presence of the immunodominant, variable head domain of HA is challenging. We report the design of a thermotolerant, disulfide-free, and trimeric HA stem-fragment immunogen which mimics the native, prefusion conformation of HA and binds conformation specific bnAbs with high affinity. The immunogen elicited bnAbs that neutralized highly divergent group 1 (H1 and H5 subtypes) and 2 (H3 subtype) influenza virus strains in vitro. Stem immunogens designed from unmatched, highly drifted influenza strains conferred robust protection against a lethal heterologous A/Puerto Rico/8/34 virus challenge in vivo. Soluble, bacterial expression of such designed immunogens allows for rapid scale-up during pandemic outbreaks.

H5-based DNA constructs derived from selected highly pathogenic H5N1 avian influenza virus induce high levels of humoral antibodies in Muscovy ducks against low pathogenic viruses.

BackgroundH5 low pathogenic avian influenza virus (LPAIV) infection in domestic ducks is a major problem in duck producing countries. Their silent circulation is an ongoing source of potential highly pathogenic or zoonotic emerging strains. To prevent such events, vaccination of domestic ducks might be attempted but remains challenging. Currently licensed vector vaccines derived from H5N1 HPAIV possess clade 0, clade 2.2 or clade 2.3.4 HA sequences: selection of the best HA candidate inducing the largest cross protection is a key issue. For this purpose, DNA immunization of specific pathogen free Muscovy ducks was performed using different synthetic codon optimized (opt) or native HA genes from H5N2 LPAIV and several H5N1 HPAIV clade 2.1, 2.2.1 and 2.3.4. Humoral cross-immunity was assessed 3 weeks after boost by hemagglutination inhibition (HI) and virus neutralization (VN) against three French H5 LPAIV antigens.FindingsVaccination with LP H5N2 HA induced the highest VN antibody titre against the homologous antigen; however, the corresponding HI titre was lower and comparable to HI titres obtained after immunization with opt HA derived from clades 2.3.4 or 2.1. Compared to the other HPAIV-derived constructs, vaccination with clade 2.3.4 opt HA consistently induced the highest antibody titres in HI and VN, when tested against all three H5 LPAIV antigens and H5N2 LPAIV, respectively: differences in titres against this last strain were statistically significant.ConclusionThe present study provides a standardized method to assess cross-immunity based on HA immunogenicity alone, and suggests that clade 2.3.4-derived recombinant vaccines might be the optimal candidates for further challenge testing to vaccinate domestic Muscovy ducks against H5 LPAIV.

H5N1 influenza vaccine quality is affected by hemagglutinin conformational stability

ABSTRACT Since 1997, highly pathogenic H5N1 avian influenza viruses have circulated in wild and domestic birds and sporadically have infected humans. Conventional inactivated vaccines made from these viruses were shown to have decreased HA content and immunogenicity compared to seasonal preparations. We assumed that the high pH threshold (5.6-6.0) known for the HA conformational change (pH of fusion or activation) of avian highly pathogenic influenza viruses was the reason of the low stability of native HA conformation and affected the vaccine quality. The 58Lys→Ile mutation introduced into the HA2 subunit of the HA of A/chicken/Kurgan/5/05 (H5N1) virus decreased the pH threshold of the HA activation. The mutant virus demonstrated increased HA stability toward acidic pH and elevated temperature, decreased binding efficiency to the monoclonal antibody IIF4 that recognizes the HA low pH form, and increased HA resistance to trypsin digestion. Virus with modified HA was less susceptible to freezing stress and showed an increased content of immunocompetent HA in inactivated vaccine preparation compared to the analogous virus with original HA. Therefore, we have shown a way to increase the quality of inactivated vaccines made from highly pathogenic avian influenza viruses.

Влияние конформационной стабильности гемагглютинина вируса гриппа на качество инактивированных вакцин H5N1

Начиная с 1997 года, в популяции диких и домашних птиц наблюдается постоянная циркуляция высокопатогенных вирусов гриппа подтипа H5N1. Периодически эти вирусы инфицируют людей, что создает угрозу возникновения новой пандемии. При производстве инактивированных вакцин из вирусов H5N1 замечено, что содержание главного компонента – антигена гемагглютинина (HA) – гораздо ниже, чем в аналогичных препаратах сезонных вирусов гриппа. Мы предположили, что урожайность НА определяется его стабильностью. Белки HA, входящие в состав вирионов высокопатогеннных вирусов гриппа птиц, отличаются от HA человеческих изолятов вируса гриппа высоким порогом рН-слияния, или рН-активации (5.6–6.0 vs 5.0–5.4), – значение pH, при котором НА изменяет конформацию, переходя в форму, необходимую для проникновения вируса в клетку. Нами получен мутантный вариант НА вируса A/chicken/Kurgan/5/05 (H5N1) с единственной заменой 58Lys→Ile, находящейся в HA2 субъединице белка. По сравнению с НА дикого типа у мутантного варианта порог рН-активации снижен, а стабильность увеличена как в кислой среде, так и при повышенной температуре. Кроме того, вирионы, содержащие мутантный НА, оказались более устойчивы к расщеплению трипсином и при их замораживании/размораживании нативная структура шипов HA сохранялась лучше, чем в родительском вирусе. Повышенная стабильность мутантного НА коррелировала с увеличением его продукции как антигена в вакцинном препарате. Таким образом, высокое значение рН-активации НА высокопатогенных штаммов вируса гриппа H5N1 определяет низкую конформационную стабильность НА и, как следствие, низкую стабильность вирионов, что влияет на качество получаемых из них вакцинных препаратов.

SAT0319 Development of Crosslinked Hydrogels of Recombinant Hyaluronic Acid for Osteoarthritis Applications

BackgroundHyaluronic acid (HA), a natural linear polysaccharide, is ubiquitous in human and animal tissues, where it exhibits significant structural, rheological, physiological, and biological functions.1 HA is widely used in the...

The CD44/integrins interplay and the significance of receptor binding and re-presentation in the uptake of RGD-functionalized hyaluronic acid

We have studied the interplay between two endocytic receptors for a carrier structure bearing two complementary ligands. Hyaluronic acid (HA; three different molecular weights) was functionalized with an RGD-containing peptide; this ancillary ligand allows the macromolecule to bind to αv integrins in addition to the classical HA internalization receptor (CD44). The uptake of HA-RGD and of native HA was assessed in a phagocytic cell model (J774.2 murine macrophages), studying the kinetics of internalization and its mechanistic details. Indications of a synergic binding to integrins and CD44 emerged for HA-RGD; possibly, a first binding to integrins allows for a pre-concentration of the macromolecule on the cell surface, which is then followed by its binding to CD44. The endocytic mechanism and kinetics appeared then dominated by CD44, which has a much slower turnover than integrins. In this study we have demonstrated that the knowledge of the rate-determining steps of the internalization of a carrier is necessary for assessing its performance. In this case, the presence of multiple ligands on a carrier was beneficial in some respect (e.g. in improved binding/targeting), but may not be sufficient to overcome penetration barriers that arise from slow receptor re-presentation.

Comments on Point:Counterpoint: High altitude is/is not for the birds!

TO THE EDITOR: The debate between Scott et al. (6) and Llanos et al. (4) highlights the remarkable ability of birds and mammals to adapt and survive at high altitudes and cope with reduced oxygen (O2) availability. Scott and colleagues (6) make a compelling argument that birds are far superior to mammals at adapting and thriving in hypoxic environments, both at rest and during exercise. While their argument is supported by comparisons between birds and terrestrial mammals, it ignores marine mammals. Marine mammals such as seals are routinely exposed to and tolerate long bouts of hypoxia during breath-hold diving. For example, elephant seals may dive to depths of nearly 1,600 m and occasionally remain submerged for 2 h (3). Moreover, marine mammals can be exposed to partial pressures of arterial oxygen (PaO2) as low as 12 mmHg during free dives (5), which is less than the 20 mmHg observed in the bar-headed goose (6). Interestingly, a PaO2 of 12 mmHg observed in elephant seals corresponds to arterial saturations and O2 content of only 8% and 2.7 ml O2/dl (5). Thus marine mammals such as the elephant seal demonstrate a remarkable hypoxia tolerance. The integration of several key physiological adaptations including 1) substantially greater myoglobin concentrations compared to other mammals, 2) reductions in metabolism, 3) a greater reliance on aerobic metabolism (i.e., less lactate production), 4) a host of dramatic acute cardiovascular adjustments; and 5) an increased intrinsic cerebral hypoxia tolerance allow marine mammals to thrive in hypoxic environments and enable long deep dives (1–3).

Functional surfaces for high-resolution analysis of cancer cell interactions on exogenous hyaluronic acid

Hyaluronic acid, a nonsulfated, linear glycosaminoglycan, is ubiquitously distributed in the extracellular matrix and is known to facilitate tumor progression by enhancing invasion, growth, and angiogenesis. Native HA has been attached to substrates to create patterned surfaces resistant to cell adhesion, and has been utilized in a variety of cell adhesion studies using either non covalently bound layers patterned by soft lithography or related methods. We use a new approach to study cell interactions with HA-presenting regions, by covalently linking HA adjacent to PEG-ylated regions, which resist cell adhesion. Colon and breast cancer cells seeded on the patterned HA surfaces adhere preferentially on HA-presenting regions and proliferate there. Furthermore, we demonstrate that cell adhesion is inhibited with the blocking of HA receptor, CD44, and that cellular adhesive processes, through protrusions spreading onto the HA surface, enhance spreading and movement outside the HA-presenting regions. Overall, this approach allows high-resolution analysis of cancer cell attachment, growth, and migration on exogenous native HA.

The impact of hyaluronic acid oligomer content on physical, mechanical, and biologic properties of divinyl sulfone‐crosslinked hyaluronic acid hydrogels

In recent studies, we showed that exogenous hyaluronic acid oligomers (HA-o) stimulate functional endothelialization, though native long-chain HA is more bioinert and possibly more biocompatible. Thus, in this study, hydrogels containing high molecular weight (HMW) HA (1 x 10(6) Da) and HA-o mixtures (HA-o: 0.75-10 kDa) were created by crosslinking with divinyl sulfone (DVS). The incorporation of HA-o was found to compromise the physical and mechanical properties of the gels (rheology, apparent crosslinking density, swelling ratio, degradation) and to very mildly enhance inflammatory cell recruitment in vivo; increasing the DVS crosslinker content within the gels in general, had the opposite effect, though the relatively high concentration of DVS within these gels (necessary to create a solid gel) also stimulated a mild subcutaneous inflammatory response in vivo and VCAM-1 expression by endothelial cells (ECs) cultured atop; ICAM-expression levels remained very low irrespective extent of DVS crosslinking or HA-o content. The greatest EC attachment and proliferation (MTT assay) was observed on gels that contained the highest amount of HA-o. The study shows that the beneficial EC response to HA-o and biocompatibility of HA is mostly unaltered by their chemical derivatization and crosslinking into a hydrogel. However, the study also demonstrates that the relatively high concentrations of DVS, necessary to create solid gels, compromise their biocompatibility. Moreover, the poor mechanics of even these heavily crosslinked gels, in the context of vascular implantation, necessitates the investigation of other, more appropriate crosslinking agents. Alternately, the outcomes of this study may be used to guide an approach based on chemical immobilization and controlled surface-presentation of both bioactive HA-o and more biocompatible HMW HA on synthetic or tissue engineered grafts already in use, without the use of a crosslinker, so that improved, predictable, and functional endothelialization can be achieved, and the need to create a mechanically compliant biomaterial for standalone use, circumvented.