Steve Lacroix is Professor in the Department of Molecular Medicine at the Faculty of Medicine of Laval University. He received his Ph.D. from Laval University in 1998. He was trained as a postdoctoral fellow in the field of spinal cord regeneration at the University of California, San Diego, under the supervision of Dr. Mark H. Tuszynski from 1998 to 2001. From 2001 to 2003, he completed a second postdoctoral training in neuroimmunology at McGill University with Dr. Samuel David. Since 2003, Dr. Lacroix runs a laboratory specialized in neuroimmunology and regenerative medicine at Centre de recherche du CHU de Québec – Université Laval (CRCHUQc-UL). Recent research conducted in his lab has focused on the identification of endogenous danger signals, or damage-associated molecular patterns (DAMPs), initiating neuroinflammation and the role of immune cells and molecules in neural damage and repair in the context of spinal cord and peripheral nerve injury, as well as multiple sclerosis. In 2017, Dr. Lacroix was named the director of the Neurosciences Axis at CRCHUQc-UL, a working group that includes 45 regular and associate researchers.

Manipulating the neuroimmune response to promote spinal cord repair

Research conducted over recent years has greatly contributed to demonstrate the importance of the immune response in the mechanisms of degeneration and regeneration of the central nervous system (CNS). Multiple sclerosis, for example, is a neuroinflammatory disease that results in the attack of nerve cells and myelin sheaths by auto-aggressive immune cells. Paradoxically, immune cells could positively influence regeneration of injured axons in models of peripheral nerve and spinal cord injury. Other studies have however shown that the immune response may also contribute to secondary tissue damage and formation of the glial scar in the injured CNS. While the results of these studies seem diametrically opposed at first sight, recent work in the Lacroix laboratory suggests that these differences could be due to the existence of different subtypes of immune cells with distinct properties (pro- vs. anti-inflammatory, trophic vs. cytotoxic, pro- vs. anti-angiogenic). Hence, a better understanding of the biological roles of the different subtypes of immune cells and mechanisms regulating their functions in the injured/diseased CNS could lead to significant contributions to basic research and even clinical opportunities. Research currently underway in the laboratory focuses on three different disorders:

Spinal cord injury (SCI): Unlike the peripheral nervous system (PNS), the CNS has a very limited capacity to regenerate. Thus, when an injury is inflicted to the spinal cord or brain, permanent deficits are often generated. Current work focuses on harnessing the neuroimmune response to reduce neural tissue loss at the site of lesion and promote functional regeneration of injured axons.

Peripheral nerve lesion (PNL): Despite the ability of peripheral nerves to regenerate, recovery of neurological function after PNL is often incomplete. Peripheral nerve injury can also lead to increased pain sensation. The Lacroix laboratory has recently demonstrated the importance of the immune response in regeneration of injured peripheral axons, recovery of motor function, and the development of neuropathic pain. In years to come, they intend to continue their efforts towards understanding the effects of inflammation in the injured PNS, in an attempt to identify (and eventually manipulate) immune cells and genes regulating neural repair and regeneration.

Multiple sclerosis (MS): In MS, an unknown trigger causes immune cells to transgress the tolerance rule, causing the body’s own immune system to turn against itself and attack the myelin and axons responsible for transmission of nerve impulses. Research conducted in the laboratory over the recent years aims at understanding how the activity and recruitment of immune cells are regulated during MS, with a special focus on cytokines of the interleukin-1 family, in the hope of finding a way to neutralize or stimulate them for therapeutic purposes.

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72 entries « 7 of 8 »

Rivest S, Nadeau S, Lacroix S, Laflamme N

Proinflammatory signal transduction pathways in the CNS during systemic immune response

Book Chapter

Berczi I, Gorczynski RM (Ed.): New foundation of biology, 1 , pp. 163-173, Amsterdam, Elsevier, 2001, ISBN: 044450754X.

Lacroix S, Tuszynski MH

Neurotrophic factors and gene therapy in spinal cord injury

Journal Article

Neurorehabil Neural Repair, 14 (4), 2000.

Abstract | Links:

Rivest S, Lacroix S, Vallières L, Nadeau S, Zhang J, Laflamme N

How the blood talks to the brain parenchyma and the paraventricular nucleus of the hypothalamus during systemic inflammatory and infectious stimuli

Journal Article

Proc Soc Exp Biol Med, 223 (1), 2000.

Abstract | Links:

Laflamme N, Lacroix S, Rivest S

An essential role of interleukin-1beta in mediating NF-kappaB activity and COX-2 transcription in cells of the blood-brain barrier in response to a systemic and localized inflammation but not during endotoxemia

Journal Article

J Neurosci, 19 (24), 1999.

Abstract | Links:

Lacroix S, Feinstein D, Rivest S

The bacterial endotoxin lipopolysaccharide has the ability to target the brain in upregulating its membrane CD14 receptor within specific cellular populations

Journal Article

Brain Pathol, 8 (4), 1998.

Abstract | Links:

Lacroix S, Rivest S

Effect of acute systemic inflammatory response and cytokines on the transcription of the genes encoding cyclooxygenase enzymes (COX-1 and COX-2) in the rat brain

Journal Article

J Neurochem, 70 (2), 1998.

Abstract | Links:

Cicchetti F, Lacroix S, Beach TG, Parent A

Calretinin gene expression in the human thalamus

Journal Article

Brain Res Mol Brain Res, 54 (1), 1998.

Abstract | Links:

Lacroix S, Rivest S

Functional circuitry in the brain of immune-challenged rats: partial involvement of prostaglandins

Journal Article

J Comp Neurol, 387 (2), 1997.

Abstract | Links: 3.0.co;2-r" title="Follow DOI:10.1002/(sici)1096-9861(19971020)387:2<307::aid-cne11>3.0.co;2-r" target="_blank">

Vallières L, Lacroix S, Rivest S

Influence of interleukin-6 on neural activity and transcription of the gene encoding corticotrophin-releasing factor in the rat brain: an effect depending upon the route of administration

Journal Article

Eur J Neurosci, 9 (7), 1997.

Abstract | Links:

Lacroix S, Rivest S

Role of cyclo-oxygenase pathways in the stimulatory influence of immune challenge on the transcription of a specific CRF receptor subtype in the rat brain

Journal Article

J Chem Neuroanat, 10 (1), 1996.

Abstract | Links:

72 entries « 7 of 8 »
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Active projects

  • Elucidating the role of the IL-1 system in the pathogenesis of CNS autoimmunity, from 2020-04-01 to 2025-03-31
  • Platelets and neutrophils: the two culprits mediating pain in inflammatory arthritis, from 2020-04-01 to 2025-03-31
  • Role of inflammation in recovery after spinal cord injury, from 2021-04-01 to 2026-03-01
  • Untangling secondary degeneration and pain from inflammation after spinal cord injury, from 2024-07-01 to 2026-06-30

Recently finished projects

  • Interleukin-1 alpha mediates secondary degeneration and neuropathic pain after spinal cord injury, from 2020-04-01 to 2023-06-30
  • Manipulating the neuroimmune response to promote spinal cord repair, from 2019-04-01 to 2024-03-31
  • Platelets and neutrophils: the two culprits mediating pain in inflammatory arthritis, from 2020-01-01 to 2022-12-31
  • The identification of the molecular mechanisms through which neuronal interleukin-1 receptors mediate pain in chronic inflammatory diseases , from 2023-04-17 to 2024-03-31
  • Thérapie génique ciblée dans un modèle de sclérose en plaques, from 2021-05-01 to 2024-04-30
Data provided by the Université Laval research projects registery