In ovo injection of probiotic combinations and their impact on broiler chick performance, immune response, and gastrointestinal development

Beck, Chrysta

13 December 2019

As the international poultry industry searches for antibiotic alternatives, dietary probiotic supplementation has exhibited the ability to decrease FCR, increase live weight gain, and regulate inflammatory responses within the gut of broiler chickens. The in ovo (or in egg) supplementation of probiotics has the potential for promoting early colonization of probiotic bacteria in the gastrointestinal tract and providing enhanced protection against pathogens in the hatchery and grow-out facilities. In the present studies, the in ovo injection of either L. animalis + E. faecium combination or L. animalis + B. licheniformis combination on d 18 of incubation does not negatively affect the chick’s ability to hatch out of the egg. These combinations also influence post-hatch performance, where FCR, gastrointestinal tissue weights, and immune-physiological parameters were impacted under non-challenged and coccidiosis-challenged grow-out conditions. These results indicate the physiological and immunomodulatory role that beneficial bacteria may have on a developing chick.

in ovo injection

hatchability

probiotic

broiler performance

chick health

antibiotic alternatives

Chloroplasts as bioreactors : high-yield production of active bacteriolytic protein antibiotics

Oey, Melanie

January 2008

Plants, more precisely their chloroplasts with their bacterial-like expression machinery inherited from their cyanobacterial ancestors, can potentially offer a cheap expression system for proteinaceous pharmaceuticals. This system would be easily scalable and provides appropriate safety due to chloroplasts maternal inheritance. In this work, it was shown that three phage lytic enzymes (Pal, Cpl-1 and PlyGBS) could be successfully expressed at very high levels and with high stability in tobacco chloroplasts. PlyGBS expression reached an amount of foreign protein accumulation (> 70% TSP) that has never been obtained before. Although the high expression levels of PlyGBS caused a pale green phenotype with retarded growth, presumably due to exhaustion of plastid protein synthesis capacity, development and seed production were not impaired under greenhouse conditions. Since Pal and Cpl-1 showed toxic effects when expressed in E. coli, a special plastid transformation vector (pTox) was constructed to allow DNA amplification in bacteria. The construction of the pTox transformation vector allowing a recombinase-mediated deletion of an E. coli transcription block in the chloroplast, leading to an increase of foreign protein accumulation to up to 40% of TSP for Pal and 20% of TSP for Cpl-1. High dose-dependent bactericidal efficiency was shown for all three plant-derived lytic enzymes using their pathogenic target bacteria S. pyogenes and S. pneumoniae. Confirmation of specificity was obtained for the endotoxic proteins Pal and Cpl-1 by application to E. coli cultures. These results establish tobacco chloroplasts as a new cost-efficient and convenient production platform for phage lytic enzymes and address the greatest obstacle for clinical application. The present study is the first report of lysin production in a non-bacterial system. The properties of chloroplast-produced lysins described in this work, their stability, high accumulation rate and biological activity make them highly attractive candidates for future antibiotics. / Lytische Enzyme aus Bakteriophagen bieten Eigenschaften, die sie zu vielversprechenden Medikamenten im Einsatz gegen bakterielle Krankheiten machen. Obwohl sie speziell beim Einsatz gegen bakterielle Infektionen, welche durch Antibiotika resistente Erreger hervorgerufen werden, eine maßgebende Rolle spielen könnten, waren bisher die hohen Produktionskosten ein Hindernis für die medizinische Anwendung. Ein kostengünstiges und einfach zu handhabendes System, wie beispielsweise Chloroplasten in Pflanzen, würde diese lytischen Enzyme zu einer effizienten Alternative zu herkömmlichen Antibiotika machen. In dieser Arbeit wird erstmals die erfolgreiche Produktion von lytischen Enzymen in Tabak-Chloroplasten vorgestellt, welche mit einem Fremdproteingehalt von mehr als 70% des gesamtlöslichen Proteins der Pflanze eine Menge beschreibt, die bisher mit diesem Verfahren noch nicht erreicht wurde. Alle in Chloroplasten hergestellten lytischen Enzyme zeigten hohe spezifische bakteriolytische Aktivität gegen die gewählten Humanpathogene und waren innerhalb von Minuten in der Lage diese Bakterien abzutöten. Zur Herstellung von zwei lytischen Enzymen wurde in dieser Arbeit ein spezieller Shuttle-Vektor entworfen, der die Expression von toxischen Genen innerhalb von E. coli Zellen im Zuge der DNA Replikation vermeidet, jedoch die Herstellung einer ungehinderten Expression der toxischen Gene in den Chloroplasten nach Beseitigung des Selektionsmarkers erlaubte. Ein Vergleich zwischen einem herkömmlich verwendeten Transformationsvektor und dem Shuttle-Vektor mittels eines Reportergens zeigte, dass das neu entwickelte System bis zu 4 mal mehr Protein produzierte. Diese Ergebnisse zeigen das Potential von Chloroplasten als kostengünstige und leicht zu handhabende Produktionsplattform für lytische Enzyme, welche als neue Generation von Antibiotika attraktive Alternativen zu herkömmlichen Therapien bieten.

Phagenlysine

Chloroplastentransformation

Antibiotikaersatz

Antibiotikaresistenz

Phage lysins

Chloroplast transformation

Antibiotic alternatives

Antibiotic resistance

Life sciences

Control of Salmonella Gallinarum (Fowl Typhoid) in Poultry with Phage-based Interventions

Saud Ur Rehman (13162020)

27 July 2022

<p>The  Pakistan  poultry  industry  has  developed  into  the  11thlargest  poultry  industry  in  the world  and  poultry  products  provide  high-quality  and  affordable  protein  sources  to  communities throughout the country. However, <em>Salmonella </em>Gallinarum, the etiological agent for fowl typhoid, is  endemic  in  Pakistan  with  infections  leading  to  high  mortality  and  substantial  economic  loss. Currently, <em>Salmonella </em>Gallinarum  infectionsin  Pakistan  poultry  are  controlled  with  antibiotics. The continued emergence of antibiotic resistance, however, has led to global initiatives to reduce the  use  of  antibiotics  in  both  human  and  veterinary  medicine.  Concurrently,  the  Pakistan government  recently  introduced  new  national  policies  that  limit  the  use  of  antibiotics  for performance  in  livestock  and  poultry  production.  As  such,  controlling  bacterial  infections  in poultry  without  increasing  the  likelihood  of  antibiotic use could  ensure  the  sustainability  of Pakistan  poultry  production  without  posing  risks  to  public  health.  Toward  this  end,  we hypothesized that <em>Salmonella</em> Gallinarum infections inchickens could be prevented or otherwise controlled through the use of phages. To test this hypothesis, wastewater samples were collected from Lahore, Pakistan and different cities of Indiana, US and processed to isolate bacteriophages. The  phages  were  characterized  in  terms  of  morphology,  host  spectra,  lytic  capacity,  genomic sequencing,  and  survivability  in  different  environments. Transmission  electron  microscopy showed these phages belonged to myoviridae (n = 5) and podoviridae (n = 1) families. Spectrum analysis  revealed  that  each  phage  lysed  at  least  8  out  of  10  different  strains  of <em>Salmonella </em>Gallinarum and significantly reduced (P < 0.05) <em>Salmonella </em>Gallinarum when co-cultured in liquid medium with the bacterium. Stability of the phages was tested insimulated gastric fluid (SGF; pH= 2.5) andsimulated intestinal fluid (SIF; pH~6.8). Results showed that phage concentrationswere reduced to undetectable levels when exposed to SGF for more than 5 minutes. However, exposure to SIF did not result in appreciable reductions in phage concentrations. To mitigate potential effects of  gastric  environments,  phages  were  encapsulated  using  a  sodium  alginate-based  method.  In contrast  to  unprotected  phages,  encapsulated  phages  remained  viable  (~100%)  after  30  minutes exposure to SGF. Additionally, encapsulation efficiencies ranged between 90-99%. Encapsulated phages were sequentially incubated in SGF (30 minutes) and SIF(120 minutes) to determine the rate  of  release  of  the  phages  from  capsules. All  phages  were  released from  capsules after  60 minutes  of  exposureto  SIF. To  determine  if  the  phages  effectively  controlled <em>Salmonella </em>Gallinarum infections in chickens, 100, day-old Jumbo Cornish Rock Cross birds were randomly assigned  to  one  of  four  treatments:  1)  Control 1  (bacterial  challenge,  no  phage  treatment);  2) Control 2 (no phage or bacterial challenge); 3) challenged with SalmonellaGallinarum and treated with  unprotected  phages;  and  4)  challenged  with <em>Salmonella</em> Gallinarum  and  treated  with encapsulated phages. At7 d of age, chicks receiving the bacterial challenge were administered 5 X106CFU (500 μL) of <em>Salmonella</em> Gallinarum. For birds in phage treatment groups, the phages were administered (500 uL; 5 X108 PFU/mL or g) at 0, 12, and 24 hours post-challenge. Six birds from each group were euthanized at 1, 2, and 4 days post-challenge (dpc) and cecal SalmonellaGallinarum  concentrations  were  quantified.  At 1  dpc, birds  treated  with  unprotected  and encapsulated  phages  had significantly lower (P  <  0.05) SalmonellaGallinarum concentrations(4.36 ± 0.20and 5.05 ± 0.22 logCFU/g, respectively) than those found in untreated birds (5.71 ± 0.13). Likewise,  at4  dpc, <em>Salmonella </em>Gallinarum concentrationsin  ceca  of  birds  treated  with encapsulated and unprotected phages were significantly lower (P < 0.05; 3.26 ± 0.62 and 4.02 ± 0.15 log  CFU/g,  respectively)  than  those  found  in untreated  birds(4.65  ±  0.08log  CFU/g). A second trial was conducted with higher challenge doses (1 mL at 1× 109CFU) and an additional treatment including a mixture (1:1) of unprotected and encapsulated phages. At1dpc, <em>Salmonella</em> Gallinarum concentrations  in the ceca  of  birds  treated  with unprotected  phages,  encapsulated phages, and a mixture of unprotected  and encapsulated phages  were significantly lower(4.28 ± 0.11, 3.72 ± 0.40, and 3.81 ± 0.36log CFU/g, respectively) than found in those of untreated birds (5.26 ± 0.19log CFU/g). At 2 dpc, concentrations of<em> Salmonella </em>Gallinarumin the ceca of birds treated  with  unprotected,  encapsulated,  and  a mixture  of  unprotected  and  encapsulated  phages were significantly  lower  (P  <  0.05; 4.31  ±0.53, 3.96  ±0.61,  and 4.38  ±  0.44logCFU/g, respectively) than those found in the ceca of untreated birds (5.72 ± 0.27logCFU/g).However, no significant differences were found in concentrations of <em>Salmonella</em> Gallinarum in the ceca of birds treated with encapsulated phages versus those treated with unprotected phagesor a mixture of   encapsulated   and   unprotected   phages.   Similarly,   at   4   dpc, <em>Salmonella </em>Gallinarum concentrations in the ceca  of  birds  treated  with unprotected  phages, encapsulated  phages,  and  a mixture of unprotected and encapsulated phages were significantly lower (3.17 ± 0.45, 3.56 ± 0.51, and 3.81 ± 0.54log CFU/g, respectively) than found in those of untreated birds (5.79 ± 0.08log CFU/g). At  7  d  post-challenge,  concentrations of <em>Salmonella</em> Gallinarum in  the  ceca  of  birds treated  with mixture  of  unprotected  and  encapsulated phages(2.40  ±  0.55log  CFU/g)  were significantly lower (P  <  0.05) than  those  found  in the ceca  of  untreated  birds(7.08  ±  0.19log CFU/g). Similarly,  concentrations of<em> Salmonella</em> Gallinarum  in the  ceca of  birds  treated  with encapsulated and unprotected phages were significantly lower (P < 0.05; 4.29 ± 0.39and 4.60 ± 0.37 log  CFU/g,  respectively)  than  those  found  in  untreated  birds.  Taken  together,  these  data indicate that <em>Salmonella </em>Gallinarum infections could be controlled with phage-based treatments. Additionally, the use of a mixture of unprotected and encapsulated phages may be more effective, presumably  by  allowing  unprotected  phages  to  act  immediately  in  the  proximal  gastrointestinal tract  (GIT;  e.g.,  crop)  with  encapsulated  phages  having  greater  activity  once  released  from capsules in the distal small intestine. While no deleterious effects of the phages were observed on the chickens themselves, continuing studies should more comprehensively assess host-response to phage treatment including potential impact on microbial communities throughout the chicken GIT.</p>

Salmonella Gallinarum

Fowl Typhoid

Phage Therapy

Antibiotic resistance

Antibiotic alternatives

Discovery of Novel Antibacterial Agents against Avian Pathogenic Escherichia coli (APEC): Identification of Molecular Targets, Assessing Impact on Gut Microbiome and Evaluating Potential as Antibiotic Adjuvants

Kathayat, Dipak

January 2021

No description available.

Animal Diseases

Microbiology

Molecular Biology

Molecules

Pharmaceuticals

Therapy

Bioinformatics

APEC

chickens

small molecules

antimicrobial peptides

antibiotic adjuvants

LptDE complex

lipopolysaccharide

MlaA-OmpC system

phospholipid

antibacterial discovery

antibiotic resistance

microbiome

colistin

PmrAB system

antibiotic alternatives