Doc­tor’s Note with Dr Amir Khan | AL JAZEERA

● The next gen­er­a­tion of shots will of­fer a broad­er and more ro­bust im­mune re­sponse. Plus, why it is im­por­tant to mon­i­tor known HIV vari­ants ●

(AL JAZEERA) — The COVID-19 pan­dem­ic caused by the se­vere acute res­pi­ra­to­ry coro­n­avirus (SARS-CoV-2) con­tin­ues to be a glob­al threat. Mil­lions of lives have been lost to the ill­ness and many con­tin­ue to suf­fer on­go­ing symp­toms long af­ter they have cleared their ini­tial in­fec­tion. While we have ad­vanced in our knowl­edge of the virus, and now have med­i­cines that have proven ef­fec­tive in treat­ing it, we still have some way to go in fu­ture-proof­ing the vac­cines that are cur­rent­ly in use to help pre­vent se­ri­ous ill­ness from the virus.

De­vel­op­ing vac­cines is no­to­ri­ous­ly dif­fi­cult and the cre­ation of the COVID-19 vac­cines has been an un­prece­dent­ed achieve­ment. But while the dis­tri­b­u­tion of the cur­rent vac­cines must con­tin­ue through­out the world, we should al­so be look­ing ahead to the next gen­er­a­tion of vac­cines that will pro­vide a broad­er and more ro­bust im­mune re­sponse.

Sec­ond-gen­er­a­tion COVID-19 vac­cines will need to build up­on the suc­cess of the cur­rent ones. Where­as the wide­ly used mR­NA vac­cines stim­u­late an im­mune re­sponse to the SARS-CoV-2 spike pro­tein, we have re­cent­ly seen that mu­ta­tions and new vari­ants can change the struc­ture of this part of the virus, mak­ing the vac­cines less ef­fec­tive. The next gen­er­a­tion of vac­cines should be made with the aim of pro­tect­ing us against cur­rent and fu­ture vari­ants, no mat­ter how in­fec­tious or vir­u­lent they may be.

Ad­di­tion­al­ly, fu­ture vac­cines should be able to re­duce the risk of trans­mis­sion of the virus from those who have been vac­ci­nat­ed. This means they will need to be able to re­duce vi­ral load, usu­al­ly by ini­ti­at­ing high lev­els of neu­tral­is­ing an­ti­bod­ies that can tar­get the virus be­fore it has a chance to mul­ti­ply in­side of a host and spread. We al­so need that im­mune re­sponse to be as long-last­ing as pos­si­ble, mean­ing boost­ers, if need­ed, can be spaced out.

Cru­cial­ly, if we want to tack­le this pan­dem­ic on a glob­al scale, the vac­cines need to be cheap and ac­ces­si­ble to all.

One vac­cine that is in de­vel­op­ment, which may help solve some of these is­sues, is biotech firm Grit­stone’s self-am­pli­fy­ing mR­NA (SAM) COVID-19 vac­cine, named GRT-R910. Self-am­pli­fy­ing mR­NAs have shown en­hanced anti­gen ex­pres­sion and an­ti­body pro­duc­tion at low­er dos­es com­pared with con­ven­tion­al mR­NA, sug­gest­ing this tech­nol­o­gy may im­prove im­mu­ni­sa­tion. It will then re­quire low­er dos­es and pos­si­bly less fre­quent boost­ers.

The GRT-R910 vac­cine is en­ter­ing phase 1 tri­als in the Unit­ed King­dom. As well as pro­duc­ing an­ti­bod­ies to the spike pro­tein, it is hoped it will al­so in­duce an im­mune re­sponse to oth­er pro­teins that the virus har­bours. Grit­stone said in a state­ment that GRT-R910 may trig­ger ro­bust, sus­tain­able and wide im­mune re­spons­es against SARS-CoV-2 vari­ants.

“Our SAM COVID vac­cine is de­signed to dri­ve ro­bust CD8+ T cell re­spons­es, in ad­di­tion to strong neu­tral­is­ing an­ti­body re­spons­es, of­fer­ing the promise of longer-last­ing im­mu­ni­ty, es­pe­cial­ly in more vul­ner­a­ble pop­u­la­tions,” ex­plained An­drew Allen, the CEO of Grit­stone. “Ad­di­tion­al­ly, since vi­ral sur­face pro­teins like the spike pro­tein are evolv­ing and some­times par­tial­ly evad­ing vac­cine-in­duced im­mu­ni­ty, we de­signed GRT-R910 to have broad ther­a­peu­tic po­ten­tial against a wide ar­ray of SARS-CoV-2 vari­ants by al­so de­liv­er­ing high­ly con­served vi­ral pro­teins that may be less prone to anti­genic drift.”

What this means in re­al terms is stronger, broad­er and longer-last­ing im­mune re­spons­es, which will mean less im­mune es­cape as fu­ture vari­ants in­evitably arise, and the pos­si­bil­i­ty of less fre­quent boost­er shots.

Many low-to mid­dle-in­come coun­tries have been un­able to af­ford the num­ber of COVID-19 vac­cines need­ed to in­oc­u­late their en­tire pop­u­la­tions. They are hav­ing to re­ly on pro­grammes such as the World Health Or­ga­ni­za­tion’s (WHO) CO­V­AX scheme which fa­cil­i­tates vac­cine eq­ui­ty across the world. One com­pa­ny that is specif­i­cal­ly fo­cus­ing on get­ting COVID-19 vac­cines to low-in­come na­tions is the Swedish biotech Zic­cum. It has de­vel­oped a tech­nol­o­gy to air-dry ex­ist­ing vac­cines, con­vert­ing them in­to pow­der forms that do not need to be stored or trans­port­ed at cold tem­per­a­tures. Zic­cum has part­nered with the Janssen phar­ma­ceu­ti­cal com­pa­ny in a bid to de­vel­op dry pow­der ver­sions of their vac­cines, in­clud­ing Janssen’s COVID-19 vac­cines.

Their re­search, how­ev­er, does not stop at COVID-19. They are al­so work­ing to trans­form man­u­fac­tur­ing and ac­cess to Janssen’s Ebo­la and RSV vac­cines. Zic­cum ar­gues that by us­ing its tech­nol­o­gy to air dry vac­cines, it re­moves cold-chain stor­age-re­lat­ed lo­gis­ti­cal prob­lems, so they can be de­liv­ered to more re­mote or hard-to-reach parts of the world.

In June 2021, the WHO launched its mR­NA tech-trans­fer hub in South Africa. Be­cause of the dis­crep­an­cy in ac­cess to vac­cines be­tween the rich­est and poor­est coun­tries, many re­searchers felt that the on­ly way to en­sure eq­ui­table ac­cess was for the Glob­al South to make its own.

The WHO called on phar­ma­ceu­ti­cal com­pa­nies and gov­ern­ments to share their patent­ed knowl­edge and tech­nol­o­gy of the COVID-19 vac­cines so low-to mid­dle-in­come coun­tries could pro­duce them. There was lit­tle re­sponse from the com­pa­nies, but South African biotech­nol­o­gy com­pa­ny, Afrigen Bi­o­log­ics and Vac­cines, went ahead and man­u­fac­tured its own ver­sion of the Mod­er­na COVID-19 vac­cine. The com­pa­ny, which was se­lect­ed by the WHO, chose Mod­er­na as the vac­cine to repli­cate as quite a lot of the in­for­ma­tion about the vac­cine’s man­u­fac­ture was in the pub­lic do­main. Al­so, Mod­er­na has pledged not to en­force its patent dur­ing the pan­dem­ic.

It is hoped this new “Mod­er­na mim­ic” will be ready for phase 1 tri­als by the end of 2022. Work is al­so un­der way to man­u­fac­ture the vac­cine at scale so it can be dis­trib­uted to those most in need. The WHO hopes that Afrigen will work as a hub and train oth­er com­pa­nies across the world to pro­duce the vac­cine. There are many more steps re­quired be­fore this vac­cine can be man­u­fac­tured glob­al­ly, in­clud­ing le­gal ones. But if it does work, it will take us one step clos­er to re­mov­ing poor­er coun­tries’ re­liance on wealth­i­er na­tions for their COVID-19 vac­cines.

Even if some of these new­er vac­cines nev­er make it to mar­ket for COVID-19, the knowl­edge, re­search and man­u­fac­tur­ing process­es be­ing gained through their de­vel­op­ment may bring ma­jor ben­e­fits in the realms of oth­er dis­eases. Fu­ture pan­demics are look­ing more and more like­ly and the bet­ter pre­pared we are for them, the more lives can be saved.

An illustration of a doctor wearing a lab coat and holding a clipboard with one hand and a pen in the other. A few HIV ribbons can be seen in the background. [Muaz Kory/Al Jazeera]

Is there a ‘new’ HIV vari­ant?

The Hu­man Im­mun­od­e­fi­cien­cy Virus (HIV) is one of the fastest mu­tat­ing virus­es ever stud­ied. Now a team of sci­en­tists, led by Ox­ford Uni­ver­si­ty, with key con­tri­bu­tions from the Dutch HIV Mon­i­tor­ing Foun­da­tion, have iden­ti­fied a strain of HIV, be­ing called the “VB” vari­ant, which has been found to be high­ly vir­u­lent.

Many pa­pers have re­port­ed the VB vari­ant as a “new” vari­ant of HIV, but this is un­true. Al­though the in­for­ma­tion about its vir­u­lence may be new, the vari­ant it­self is not. By analysing the pat­terns of ge­net­ic vari­a­tion among the sam­ples, the re­searchers es­ti­mate that the VB vari­ant first arose be­tween the late 1980s and 1990s in the Nether­lands. It spread more quick­ly than oth­er HIV vari­ants dur­ing the 2000s, but its spread has been de­clin­ing since about 2010.

Con­spir­a­cy the­o­rists were quick to try to spread mis­in­for­ma­tion on­line by link­ing this vari­ant to the COVID-19 vac­cines, but this has been de­bunked as the vari­ant pre­dates not just the vac­cines but COVID-19 by more than 20 years.

HIV is a virus that dam­ages the cells in your im­mune sys­tem and weak­ens your abil­i­ty to fight every­day in­fec­tions and dis­ease. Its main route of spread is through the mix­ing of bod­i­ly flu­ids such as blood and se­men. AIDS (ac­quired im­mune de­fi­cien­cy syn­drome) is the name used to de­scribe a num­ber of po­ten­tial­ly life-threat­en­ing in­fec­tions and ill­ness­es that oc­cur when your im­mune sys­tem has been se­vere­ly dam­aged by HIV. With an ear­ly di­ag­no­sis and ef­fec­tive treat­ments now avail­able, most peo­ple with HIV will not de­vel­op any AIDS-re­lat­ed ill­ness­es and will live a near-nor­mal life.

One of the ways we mon­i­tor the sever­i­ty of a HIV in­fec­tion is to mea­sure a type of white blood cell in an in­di­vid­ual called a CD4, a type of T cell. A CD4 count is used to check the health of the im­mune sys­tem in peo­ple in­fect­ed with HIV. The virus at­tacks and de­stroys CD4 cells. So if CD4 cells drop too low, then the in­di­vid­ual de­vel­ops a risk of in­fec­tion. An­oth­er way clin­i­cians mea­sure sever­i­ty of dis­ease and the ef­fect of treat­ment on those liv­ing with HIV is to mea­sure their “vi­ral load” – or the lev­el of the virus in their blood. The low­er the vi­ral load, the more ef­fec­tive the treat­ment will be, and the in­fect­ed per­son is less like­ly to pass the virus on.

Changes in ei­ther vi­ral load or CD4 count in groups of peo­ple be­ing mon­i­tored can al­so give an in­di­ca­tion as to whether HIV has mu­tat­ed or changed course. The au­thors of a study mon­i­tored the blood of more than 100 peo­ple in the Nether­lands with a spe­cif­ic vari­ant of HIV called sub­type-B HIV-1, which is now be­ing dubbed “VB”. They then com­pared the changes in their blood to 6,604 in­di­vid­u­als with oth­er sub­type-B strains and found the fol­low­ing:

   1.     In­di­vid­u­als with the VB vari­ant had a vi­ral load (the lev­el of the virus in the blood) be­tween 3.5 and 5.5 times high­er

   2.     The rate of CD4 cell de­cline (the hall­mark of im­mune sys­tem dam­age by HIV) oc­curred twice as fast in in­di­vid­u­als with the VB vari­ant, plac­ing them at risk of de­vel­op­ing AIDS much soon­er

   3.     In­di­vid­u­als with the VB vari­ant al­so showed an in­creased risk of trans­mit­ting the virus to oth­ers.

The re­as­sur­ing news is that in­di­vid­u­als with the VB vari­ant re­spond­ed just as well as those with oth­er vari­ants to HIV treat­ment; but the re­search does serve to high­light the im­por­tance of an ear­ly di­ag­no­sis and im­me­di­ate treat­ment, as these in­di­vid­u­als were at risk of pro­gress­ing to AIDS soon­er. The team of re­searchers did not analyse what makes the VB vari­ant more vir­u­lent, and more work is be­ing done on that. But it does high­light the volatil­i­ty of HIV and the im­por­tance of mon­i­tor­ing known vari­ants.

Au­thors of the study have al­so stat­ed that the pub­lic does not need to wor­ry about these find­ings; rather they re-em­pha­sise the im­por­tance of reg­u­lar test­ing, ear­ly di­ag­no­sis, and im­me­di­ate HIV treat­ment.